CR-82-093
DEPARTMENT OF DEFENSE
Electromagnetic Compatibility Analysis Center
Annapolis, Maryland 21402
[SUPPORT TO THE ENVIRONMENTAL PROTECTION AGENCY
NONIONIZING RADIATION SOURCE ANALYSIS
Prepared for
The U.S. Environmental Protection Agency
Office of Radiation Programs
Nonionizing Radiation Surveillance Branch
Washington, DC 20460
SEPTEMBER 1982
CONSULTING REPORT
Prepared by
F. H. Tushoph, Ved P. Nanda
David L. Williamson
IIT Research Institute
Under Contract to
Department of Defense
p-j .--t-ip-i tinti frn	" r 		¦¦¦¦¦¦*».	nnlYf
11 \jj 111in B^iii mi i mrr "SeptemBer 1 982T™~ Other	^
*->ii g Hnqii-ant-	.Jbe-.JCef erred to^BCAC.
(a*-U<- ! Kcc
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ECAC-CR-82-093
This report was prepared by the IIT Research Institute as part of AF
Project 649E under Contract F-19628-80-C-0042 with the Electronic Systems
Division of the Air Force Systems Command in support of the DoD
Electromagnetic Compatibility Analysis Center, Annapolis, Maryland.
This report has been reviewed and is approved for publication.
Reviewed by:
F. H. TUSHOPH
Project Manager, IITRI
WILLIAM J. GREENE
Assistant Director
Contractor Operations
Approved by:
Special Projects
Deputy Director
M. A. SKEATH

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UNCLASSIFIED
SECURITY CLASSIFICATION OF This PAGE (When Data Entered)
REPORT DOCUMENTATION PAGE
READ INSTRUCTIONS
BEFORE COMPLETING FORM
1. REPORT NUMBER 2. GOVT ACCESSION NO.
ECAC-CR-82-093
3. RECIPIENT'S CAT ALOG NUMBER
4. TITLE (and Subtitle)
SUPPORT TO THE ENVIRONMENTAL PROTECTION AGENCY
NONIONIZING RADIATION SOURCE ANALYSIS
5. TYPE OF REPORT ft PERIOD COVERED
Consulting Report
6. PERFORMING ORG. REPORT NUMBER
7 AUTHORS.)
F. H. Tushoph, Ved P. Nanda,
David L. Williamson
8. CONTRACT OR GRANT NUMBERfi)
F-19628-80-C-0042
CDRL # 10P
9. PERFORMING ORGANIZATION NAME AND ADDRESS
DoD Electromagnetic Compatibility Analysis Center
North Severn, Annapolis, MD 21402
10. PROGRAM ELEMENT. PROJECT, TASK
AREA ft WORK UNIT NUMBERS
P0314
II. CONTROLLING OFFICE NAME ANO ADDRESS
U.S. Environmental Protection Agency
Office of Radiation Programs
Nonionizing Radiation Surveillance Branch
Washington, DC 20460
12. REPORT DATE
September 1982
13. NUMBER OF PAGES
66
u. MONITORING AGENCY NAME 4 ADDRESSf// dlllerent Irom Controlling Ollice)
IS. SECURITY CLASS, (ol thle report)
UNCLASSIFIED
IS*. DECLASSIFICATION/DOWNGRADING
SCHEDULE
16. DISTRIBUTION STATEMENT (ol thle Report)
Distribution limited to U.S. Government agencies only; Test and Evaluation;
September 1982. Other requests for this document must be referred to ECAC.
<7. DISTRIBUTION STATEMENT (ol the abitract ontered In Block 20. II iltierent Irom Report)
UNLIMITED
18. SUPPLEMENTARY NOTES
19. KEY WOROS (Conttnuo on raverae aid* II naceeemry and Identify by block number)
NONIONIZING RADIATION
POWER DENSITY
RADIATION HAZARDS
20. ABSTRACT (Continu* on r«v«r«« 9id9 i/ ntctuary end Identity by block numbmr)
As a result of an interagency agreement, ECAC has provided the EPA with
a data base of communications-electronics emitters in the US&P and predictions
of power density as a function of distance for these emitters. These pre-
dictions are displayed in the form of histograms. This report describes the
techniques used to generate, evaluate, and augment the data files. It also
provides an overview of the software and the equations used to calculate
power density and produce the histograms. Sample outputs are provided.
DD ,:2nRM73 1473 EDITION OF 1 NOV 68 IS OBSOLETE
UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGE (Whin D»f Bnfrad)
i/ii

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ECAC-CR-82-093
TABLE OF CONTENTS
Subsection	Page
SECTION 1
INTRODUCTION
BACKGROUND		1
OBJECTIVES		1
APPROACH		2
LIMITATIONS		3
File Limitations .....											3
Project Limitations							3
SECTION 2
FILE GENERATION/ANALYSIS/PROGRAM DEVELOPMENT
GENERAL		5
DATA SOURCES		5
Government Master File						5
FCC File				6
ENVIRONMENTAL FILE GENERATION		6
FILE EVALUATION		7
FILE AUGMENTATION		7
DEVELOPMENT OF ANALYTICAL EQUATIONS		8
SOFTWARE DEVELOPMENT		11
OUTPUT CONTENTS AND FORMAT		11
Master Data Base		11
Histograms					12
SECTION 3
OUTPUTS	17
iii

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eCAC-CR-82-093
TABLE OF CONTENTS (Continued)
Subsection	Page
LIST OF ILLUSTRATIONS
Figure
1	Sample type A histogram	 13
2	Sample type B histogram	 14
3	Sample type C histogram	 15
LIST OF TABLES
Table
1	SPECIFIED BROADCAST STATION DATA ITEMS.			 8
2	SPECIFIED NONBROADCAST STATION DATA ITEMS	 9
3	PERCENTAGE OF FIELDS FILLED PER FILE	 10
LIST OF APPENDIXES
Appendix
A	METHODOLOGIES FOR RECOVERY OF EQUIPMENT PARAMETERS	A-1
B	ANALYTIC EQUATIONS FOR POWER DENSITY AND DISTANCE
CALCULATIONS	 B-1
C	DATA MANIPULATION PROCEDURES	 C-1
D	FORMAT AND CONTENTS FOR EPA MASTER DATA BASE	 D-1
E	SAMPLE MASTER DATA BASE PRINT	 E-1
iv

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ECAC-CR-82-093
Section 1
SECTION 1
INTRODUCTION
BACKGROUND
Hie U.S. Environmental Protection Agency (EPA), Office of Radiation
Programs, Nonionizing Radiation Surveillance Branch (NRSB), has been charged
with development and implementation of Federal Guidance on "environmental
exposure levels of radio frequency and microwave radiation" (radiation hazard
levels). As part of this development, the EPA needs to determine the
potential economic impact of any proposed guidance on owners and operators of
communications-electronics (C-E) equipments that are sources of
electromagnetic radiation. To this end, the EPA desires to identify and
catalog those sources that may be affected by any proposed guidance. The
extent to which these emitters may contribute to the electromagnetic
environment also needs to be determined. Ch 30 July 1981, the EPA and the
Electromagnetic Compatibility Analysis Center (ECAC) became signatories to an
Interagency Agreement. This agreement stated that ECAC was to provide the EPA
with a data base of certain emitters and sets of histograms that display
calculated power density as a function of distance from these emitters. The
emitters of interest to the EPA are those in the United States and Possessions
(US&P) that produce electromagnetic radiation in the 10 kHz to 100 GHz
range. These emitters include broadcast stations, radars, satellite earth
stations, and certain other transmitters. Only those sources that met EPA-
specified criteria (see Section 2) were inventoried.
OBJECTIVES
The objectives of this project were to:
1.	Produce a data base of fixed C-E emitters in the US&P.
2.	Produce histograms that display calculated power density versus
distance for the several categories of emitters.
1

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ECAC-CR-82-093
Section i
APPROACH
The approach to this project required the selection and development of
automated models tailored to: extract data from existing ECAC environmental
files, augment the data where necessary, make calculations using the data, and
produce the data base and specialized histograms. The project was divided
into four separate tasks.
1.	Data Source Identification, Evaluation, and Augmentation. The
Government Master Pile (GMF) was selected as the data source for government
frequency assignment records. The Federal Communications Commission (FCC) file
was used for non-government records. Each data file was reviewed to determine
the percentage of required data present in the file. Methods were devised to
augment the existing data, where necessary, for the calculations.
2.	Development of Analytical Equations. Chly certain
characteristics of the emitting systems under consideration were generally
available from data sources. Because of this, it was necessary to develop a
set of analytical equations to calculate power density as a function of
distance in terms of available parametric quantities (power, gain, and
frequency).
3.	Software Development. The ECAC Environmental Analysis System
(EASY) was modified and expanded to: develop a compilation of models to
manipulate the file data, augment the existing data, and make the
calculations. Test beds were developed from actual and synthesized data.
EASY was exercised on these test beds, and the results were compared to
manually calculated values to validate the accuracy of the models.
4.	Data Base and Histogram Production. The modified EASY was used
on the total file data to produce histograms and a data base. The data base
was recorded on magnetic tape and in hard-copy form for delivery to the EPA.
2

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ECAC-CR-82-093
Section 1
LIMITATIONS
File Limitations
The OIF and FCC frequency assignment files are the most suitable sources
of C-E environmental data available for this project. However, they are large
volume data files that are structured, maintained, and updated by external
agencies for the purpose of frequency management and frequency assignment
record keeping. These files are structured on the basis of one data record
per frequency assignment rather than one record per C-E emitter. Because of
their size and method of maintenance, they may contain some undetected
erroneous data values.
Project Limitations
This task was designed to calculate approximate values of power density
as a function of distance from specified emitters. Consequently, a number of
factors that influence the actual power density at a given distance from an
emitter were not considered. Among these factors are terrain, antenna height,
loading, and proximity to other objects. Because actual antenna
characteristics were unknown, the following assumptions were used in the
calculations.
1 . When the given value for gain was equal to or less than 10 dBi,
the antenna was treated as linear.
2.	When the given value for gain was greater than 10 dBi, the
antenna was treated as a circular aperature antenna with 50 percent
efficiency.
3.	The antenna gain value used in the off-axis calculations was set
equal to the main-beam gain minus 20 dB.
Because of file size, no effort was made to verify specific data values.
Where feasible, missing data values were obtained through the recovery
techniques described in APPENDIX A.
3/4

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ECAC-CR-82-093
Section 2
SECTION 2
FILE GENERATION/ANALYSIS/PROGRAM DEVELOPMENT
GENERAL
The tasks outlined in the approach subsection are described in this
section; the task details are provided in the appendixes. The discussions
include:
1.	The descriptions of the sources used as inputs
2.	The generation of the environmental files from the data sources
3.	The evaluation of the environmental files
4^ Ihe methodology used for file augmentation
5.	The development of the analytical equations
6.	The software development
7.	The contents and format of the outputs.
DATA SOURCES
In concert with the EPA, it was agreed that the US&P environment would be
generated from the GMF and FCC frequency assignment records.
Government Master File
The GMF contains over 170,000 frequency assignments records for U.S.
government stations operating in the US&P. The GMF is maintained by the
National Telecommunications and Information Administration (NTIA) for the
Interdepartment Radio Advisory Committee (IRAC). A complete updated GMF is
provided on tape to ECAC each month, and the data is processed into the ECAC
file format on a purge-and-replace basis.
5

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ECAC-CR-82-093
Section 2
FCC File
This file contains over 1,000,000 frequency assignment records for non-
government stations operating in the US&P. It is updated every 6 months on a
purge-and-replace basis.
ENVIRONMENTAL FILE GENERATION
Using the <34F and FCC source files, four environmental files were created
using the following EPA-specified criteria.
a.	Broadcast Stations. Fixed (government and non-government)
emitters in the 535 to 1605 kHz, 54 to 88 MHz, 88 to 108 MHz, 174 to 216 MHz,
and 470 to 890 MHz frequency ranges with authorized effective isotropically
radiated powers (EIRP's) of 10 watts or more.
b.	Radar Stations. Fixed (government and non-government) radar
transmitters, both pulsed and continuous wave, with a peak transmitter power
of 10 kW or greater or an average power of 100 watts or greater.
c.	Earth Stations. Fixed (government and non-government) earth
station transmitters with an average transmitter power greater than 20 watts,
operating in the space communications, research, telecommand, telemetry,
tracking, meteorological, and radionavigation services.
d.	Other Transmitting Stations. Other fixed (government and non-
government) emitters with an average transmitter power of 2 kW or greater and
operating between 10 kHz and 100 GIte. Citizen band and amateur stations were
excluded from this file.
The number of records in the four generated files are:
a.	22,298 broadcast station records (48 from the GMF and 22,250 from
the FCC file)
b.	3,598 radar station records (3,242 from the GMF and 356 from the
FCC file)
6

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ECAC-CR-82-093
Section 2
c.	1,509 earth station records (705 from the GMF and 804 from the
FCC file)
d.	11,508 other station records (10,046 from the GHF and 1,462 from
the FCC File).
FILE EVALUATION
Once constructed, the files were examined for completeness in two areas —
data availability for the data base and data availability for the calculations
producing the histograms. The EPA requested that certain data items (see
TABLES 1 and 2) be supplied in the data base. Ihese items include those
needed for the calculations. TABLE 3 is a listing of percentage of fields
(data items) filled per file. This information has been provided to the EPA1
as a guide to the completeness of the output data base. The following items
were required for the calculations:
a.	Frequency
b.	Effective isotropically radiated power (EIRP)
c.	Transmitter power
d.	Antenna gain — main beam and off axis
e.	Duty cycle
f.	Beamwidths
g.	Scan angles.
FILE AUGMENTATION
As can be noted in TABLE 3, several of the above data items required for
the calculations are not present in all records. A study was made of methods
to calculate values when data items are missing. APPENDIX A includes a
discussion of these methods as well as the methods used to handle multi-valued
data items. Ihese former methods were used successfully in every file except
the FCC radar file for which no suitable means was available for determining
1ECAC letter of 10 February 1982, subject: EPA Support.
7

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ECAC-CR-82-093
Section 2
values for duty cycle, beamwidth, or scan angle. With the EPA's concurrence,
the FCC radar file was deleted from the calculations (but is represented in
the EPA data base).
TABLE 1
SPECIFIED BROADCAST STATION DATA ITEMS
Record ID
Call sign
Transmitter (TX) location (city, state, coordinates)
Frequency
TX power output
TX effective isotropically radiated power (EIRP)
TX antenna gain
TX antenna polarization
TX antenna height above average terrain (HAT)
or TX antenna height above ground
DEVELOPMENT OF ANALYTICAL EQUATIONS
Equations for performing the required analysis were developed in concert
with the EPA. The equations were used to calculate the power density at eight
separate distances from the individual transmitter antennas (100, 200, 500,
1000, 2000, 5000, 10000, and 20000 meters) and the distances corresponding to
seven separate power densities (0.01, 0.025, 0.05, 0.1, 0.5, 1.0, and 10
mW/cm2). Separate equations were developed for transmitters with linear
antennas and those with aperture antennas. Both sets of equations take into
account near-field correction factors. The equations, the assumptions upon
which they are based, and the conditions where each is used are delineated in
APPENDIX B.
8

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ECAC-CR-82-093
Section 2
TABLE 2
SPECIFIED NONBROADCAST STATION DATA ITEMS
Record ID
Category
System nomenclature, manufacturer
TX location (city, state, coordinates)
TX operating agency
Frequency or frequency band
TX peak power
TX average power
TX duty cycle
TX pulse width used
TX pulse repetition rate used
TX antenna gain
TX antenna polarization
TX antenna type
or TX antenna nomenclature
TX antenna horizontal V2 power beam width
TX antenna vertical ^ power beam width
TX antenna illumination type
TX antenna elevation angle
TX antenna first side lobe (position and intensity)
relative to main beam level (both horizontal and vertical)
TX antenna motion type
TX antenna motion rate
TX antenna scan angle
TX antenna dimensions
TX antenna height above ground
9

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ECAC-CR-82-093
TABLE 3
PERCENTAGE OF FIELDS FILLED PER FILE
Section 2



Emitter Type
and File Source

Emi tter
Broadcast
Stations
Rada
Stati
Dns
Earth
Stations
Oth<
Stat
sr
ions
Data Item
GMF
FCC
GMF
FCC
GMF
FCC
GMF
FCC
Record ID
100
100
100
1 00
1 00
1 00
100
100
Call sign
10
100
N/A
N/A
N/A
N/A
60
100
System nomenclature
N/A
N/A
68
0
61
0
4
0
City and state
100
100
100
100
100
100
100
100
Latitude and longitude
100
100
1 00
1 00
100
100
100
100
Operating agency
100
100
100
100
100
100
100
100
Frequency
100
100
100
100
100
100
100
100
Peak power output
N/A
N/A
100
100
N/A
N/A
73
59
Average power output
100
30
0
0
100
100
27
39
EIRP
0
70
0
0
0
20
0
2
Pulse repetition rate
N/A
N/A
98
0
N/A
N/A
2
0
Pulse width
N/A
N/A
98
0
N/A
N/A
2
0
Antenna gain
46
0
85
0
100
0
32
0
Antenna polarization
25
0
81
0
100
0
8
0
Antenna type
N/A
N/A
8S
0
0
0
2
0
Antenna nomenclature
N/A
N/A
14
0
0
0
5
0
Antenna horizontal
beam width
N/A
N/A
0
0
99
0
0.5
0
Antenna vertical
beam width
N/A
N/A
0
0
0
0
0
0
Antenna elevation angle
N/A
N/A
0
0
100
0
0
0
Transmitter to first
satellite angle
N/A
N/A
N/A
N/A
99
0
0
0
Transmitter to second
satellite angle
N/A
N/A
N/A
N/A
99
0
0
0
Antenna motion type
N/A
N/A
85
0
N/A
N/A
58
0
Antenna motion rate
(horizontal)
N/A
N/A
0
0
N/A
N/A
0
0
Antenna horizontal
scan angle (from)
N/A
N/A
0
0
N/A
N/A
0
0
Antenna horizontal
scan angle (to)
N/A
N/A
0
0
N/A
N/A
0
0
Antenna fixed azimuth
N/A
N/A
N/A
N/A
N/A
N/A
14
0
Antenna height above
ground
44
2
70
45
98
33
3
5
10

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ECAC-CR-82-093
Section 2
SOFTWARE DEVELOPMENT
Specialized software was required to implement the file augmentation
procedures and analytical equations used in the analysis. Additional software
was needed to manipulate the file data and produce the histograms and data
base. The software development was divided into four phases.
1 . Definition. Precise software system requirements were generated
using guidance provided by the EPA.
2.	Design. Using a "top-down" approach, detailed descriptions of
the software elements were developed, engineering issues were resolved, and
the overalldesign reviewed.
3.	Obding. Die programs were written and verified by comparing the
code with the design and engineering specifications.
4.	Hasting. A test bed was developed from actual and synthesized
file records. The programs were executed on this test bed and the results
compared to manual calculations. The programs were also executed on the
entire input file and the resulting histograms and data base were analyzed.
APPENDIX C describes the data manipulation procedures used for the
analysis and output production. It also provides flowcharts that show how the
file data was augmented and how the analytical equations were implemented in
the analysis.
OUTPUT CONTENTS AND FORMAT
Master Data Base
The EPA Master Data Base was provided to the EPA under separate cover.
It consists of all of the unclassified emitter records considered for this
analysis. The data base was provided on nine-track magnetic tape and in hard
copy. The contents and format of the data base are described in APPENDIX D.
Sample hard-copy output for each of the four major categories of emitter
records is provided in APPENDIX E.
11

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ECAC-CR-82-093
Section 2
Histograms
Using the analytical equations, histograms were developed from the data
(both classified and unclassified) in the GMF and FCC files. Three types of
histograms are provided in the attachment to this report for each of 15
categories of emitters. The three histogram types are as follows.
1.	Type A. Shows the number of assignments for emitters which, as a
function of specified distances from the antenna, could produce a specified
minimum power density. Hie minimum specified power densities are: 0.025,
2
0.05, 0.1, 0.5, 1.0, and 10 mW/cm . (Calculations were made using the minimum
o
specified power density of 0.01 mW/cm , but no histograms were produced using
this value.)" The specified distances are: 100, 200, 500, 1000, 2000, 5000,
10000, and 20000 meters. Figure 1 is an example of a type A histogram.
2.	Type B. Shows the number of assignments for emitters which, as a
function of specified distances from the antenna, could produce a power
density whose value lies within a specified range. The specified ranges are:
<_ 0.025 mW/cm2
>	0.025 but £ 0.05 mW/cm2
>	0.05 but <_ 0.1 mW/cm2
>	0.1 but <_ 0.5 mW/cm2
>	0.5 but _< 1.0 mW/cm2
>	1.0 but <_ 10.0 mW/cm2
>	10.0 mW/cm2.
The specified distances are the same as 1 above. An example of a type B
histogram is shown in Figure 2.
3.	Type C. Shows the number of assignments for emitters which, as a
function of specified minimum power densities, could produce that power
density at a specified distance from the antenna. Ihe specified minimum power
densities and distances are as described in 1 above. An example of a type c
histogram is shown in Figure 3.
12

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OTHER STATIONS C100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS'10900
TOTAL NUMBER PROCESSED-10900
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
M
n
>
0
1
0
70
1
00
to
1
o
Go
3000
N
U
M
B
E
R
0
F
2000
G
H 1000
I
S
0
23%
2531

7%
703

IX
140
J22.
1*
91
PZ71
0X
10
0X
1
0X
0
0*
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
CO
(D
O
Figure 1. Sample type A histogram.
o
D

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EARTH STATIONS CMAINBEAKD
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED»1509
POWER DENSITY RANGE C.05-13 MW/CM2
200 -
300
N
U
M
B
E
R
0
F
A
S
S
1
H 100
E
N
T
S
19*
284
0
10*
150
I
11*
170
1
9*
143
I
10%
158
i
8%
119
1

1 1


4*
61
1
7*
102
I
100 200 500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure 2. Sample type B histogram.

-------
2000 T
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED-4037
DISTANCE FROM ANTENNA 100 METERS
pj
0
>
n
1
0
v
1
00
to
1
o
vo
w
N
U
M
B
E
R
0
F
A
5
?
G
M
6
1
1000 -
0
26*
1137

.026
21*
036

6*
223
i
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0%
0
—i—
10
to

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tCAC-CR-82-093
Section 2
The 15 categories of emitters for which histograms were produced are:
1.	AM broadcast stations (535-1605 kHz)
2.	FM broadcast stations (88-108 MHz)
3.	TV broadcast stations (54-88, 174-216, 470-890 MHz)
4.	Composite of all broadcast stations
5.	Civilian fixed beam radar stations (off-axis antenna gain only)
6.	Civilian scanning radar stations (off-axis antenna gain only)
7.	Military fixed beam radar stations (off-axis antenna gain only)
8.	Military scanning radar stations (off-axis antenna gain only)
9.	Satellite earth stations (main-beam antenna gain)
10.	Satellite earth stations (off-axis antenna gain)
11.	Other stations (10-100 kHz)
12.	Other stations (100.1 kHz-30.561 MHz)
13.	Other stations (30.5611-960.0 MHz)
14.	Other stations (above 960.0 MHz)
15.	Composite of all stations (except satellite earth stations
antenna main	beam).
16

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ECAC-CR-82-093
Section 3
SECTION 3
OUTPUTS
The outputs of this project are the Master Data Base and the histograms,
both of which were provided to the EPA under separate cover. The data base
exists on magnetic tape and in hard copy.
17/18

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ECAC-CR-82-093
Appendix A
APPENDIX A
METHODOLOGIES FOR RECOVERY OF EQUIPMENT PARAMETERS
GENERAL
A survey of the radio frequency assignment records in the Federal
Communications Commission (FCC) and Government Master Files (GMF's) indicated
that use of these files for the Environmental Protection Agency (EPA) support
project required a unique approach because of the following.
1.	Data with Multiple Values. Many of the records contained
multivalued data. For instance, frequency and power are listed as ranges or
multiples in many records.
2.	Missing Values. Many of the records contained blank data fields
for essential parameters. For instance, antenna beamwidth or scan angles were
usually not available. Similarly, antenna gain values were missing from over
80% of the records.
For this project, methods were developed for recovery of missing data and
treating multivalued data. This appendix delineates the rationale for these
methods as well as the methods themselves.
RECOVERY OF MULTIVALUED DATA
Some of the equipment categories (e.g., radar) contain multivalued data
in fields such as frequency, power, pulse width (PW), and pulse repetition
frequency (PRF). Hie multivalued data took three forms — more than one
discrete value, a range of values, and more than one range of values. It was
necessary to reduce these to discrete values for use in the analysis. The
basic criterion used in the data recovery was that the resulting discrete
values produce conservative analytical results. "Hie exception to this
criterion was the use of a mid-band recovery value for frequency, because the
center frequency is of primary interest for matching power transfer
A-1

-------
ECAC-CR-82-093
Appendix A
considerations. The multivalued data fields and the corresponding recovery
criteria used in the analysis are provided in TABLE A-1.
TABLE A-1
CRITERIA FOR MULTIVALUED DATA FIELDS
Field Name
Type
Recovery Criteria
| Frequency
Range of values
Mid-band value.
Power
Multiple discrete
values or ranges
Highest value.
!
Antenna gain
Multiple discrete
values or ranges
Highest value.
PRF/PW
Range of values
Average value.
PRF/PW
Multiple discrete
values or multiple
ranges
Duty factor was calculated
for each entry and the
highest value used.
RECOVERY OF MISSING DATA
In all categories of assignment records, various data fields important to
the analysis were found to be blank. Typical empty data fields included
antenna gain, beamwidth, and scan angle. In addition, no data field existed
in the selected files for off-axis antenna gain. The methodology devised to
recover missing values was produced in concert with the EPA and is described
below.
A-2

-------
ECAC-CR-82-093	Appendix A
Antenna Main-Beam Gain Recovery
An empirically derived equation was used for recovery of main beam
antenna gains for all file records except the FCC Earth Station File. This
equation is based on a survey of over 12,500 antenna gain values in the ECAC
data base and is given by:
G(dBi) =	A lo9l0 f + B	(A-1)
where
G(dBi) =	recovered value of main-beam antenna gain, in dBi
f «	center frequency of the record, in MHz
A, B = constants listed below.
frequency Range (MHz) A (unitless)	B (dBi)
_<_ 70	0	5.0a
70 < f2 <_ 700	10.0	-13.5
700 < f3 <_ 2000	61 .3	-159.6
2000 < f4	7.0	19.9
For the missing antenna gains in the FCC Earth Station File, it was
decided to use typical gains per band extracted from several available sources
including the 1981 Satellite Directory^ and the OIF Earth Station File.
aAntenna gains for certain categories of antennas (e.g., rhombic, Yagi, etc.)
in this band will have values between 14 and 20 dBi.
^1981 Satellite Directory, Phillips Publications, Washington, DC, 1981.
A-3

-------
ECAC-CR-82-093
Appendix A
These gains are listed below:
Band (MHz)	Antenna Gain (dBi)
33.78
-
49.58
10
148.25
-
149.82
22
151.025
-
159.915
22.5
451.05
-
471.98
13.5
852.36
-
852.46
36
1638.5
-
1642.5
42
3880.8
-
3886.8
61
4079
-
4081
61
4100
-
4105
61
4188
-
4190
61
5925
-
6425
65
14000
-
14500
60
For radars and earth stations using aperture antennas, there is a
requirement to calculate power density and distance values in the crossover-
and far-field regions using off-axis antenna gains. The antenna gain value
used in the off-axis calculations was defined as the main-beam gain (in dBi)
minus 20 dB.
Antenna Beamwidth Recovery
In the absence of any information about antenna dimensions, Equation A-2
3
was used to determine antenna beamwidth:
0q = 187	(A-2)
rc
3S. Silver, Microwave Antenna Theory of Design, Dover Publications Inc.,
New York, NY, 1965. (Equation A-2 was derived from pattern characteristics
of the circular aperture antenna listed in TABLE 6.2).
A-4

-------
ECAC-CR-82-Q93
Appendix A
where
0B = beaxnwidth of antenna between half-power points, in degrees
G = antenna gain, numeric.
Scan Angle Recovery
Approximate values for scan angles are listed in TABLE A-2. Some of
these values were obtained from the U.S. Radar Equipment Handbook.4 The
remaining values are based on engineering judgment.
TABLE A-2
SCAN ANGLE RECOVERY VALUES
Antenna Motion Type
Percentage of
Equipment Records
Recovery Value
(in degrees)
Rotating
65
360
Omni
1
360
Sector scan
2
60
Nodding
3
30
Tracking
10
0
Directional
1
0
Steering
2
0
Blank (field empty)
16
0
4U.S. Radar Equipment, MIL HDBK-162B, Department of the Navy, Washington, DC,
December 1973•
A-5/A-6

-------
ECAC-CR-82-093
Appendix B
APPENDIX B
ANALYTIC EQUATIONS FOR POWER DENSITY AND DISTANCE CALCULATIONS
GENERAL
The equations presented in this appendix are used in an automated model
to provide an estimate of free-space power density as a function of distance
from an antenna. Calculations were made for near-field, crossover region, and
far-field distances. The basic equations used are those given in References
5, 6, 7, and 8. The equations were manipulated to enable the calculation of a
power level for a given distance or a distance for a specified power level.
Because only certain characteristics of the emitting systems under
consideration were generally available from the data sources, the number of
parameters used in the equations were limited. Use of a minimum number of
parameters was possible because of the known relationships between wavelength,
gain, effective antenna area, and assumed aperture efficiency (0.5). The main
parameters employed in the computations are:
1.	Wavelength - A
2.	Power - P
3.	Antenna gain - G
4.	Effective isotropically radiated power - EIRP.
The equations developed are applicable to the on-axis (main-beam) case.
Both linear and aperture antennas are considered. Linear antennas are assumed
^Hansen, Bickmore, "Antenna Power Densities in the Fresnel Region,"
Proceedings of the IRE, December 1959.
^Hansen, R. C., Microwave Scanning Antennas, Volume 1, Academic Press, New
York, NY, 1964.
«¦*
United States Air Force Communication Service E-I Standard, T.O. 31Z-10-4,
August 1966.
^Reference Data for Radio Engineers, Fifth Edition, ITT Handbook, Howard Sam
and Co., New York, NY, 1973.
B-1

-------
ECAC-CR-82-093
Appendix B
to be those with gains of 10 dBi or less. Antennas with gains greater than
10 dBi are treated as circular aperture antennas. Hence, the equations
developed for aperture antennas are predicated on assumptions for circular
apertures.
EQUATIONS FOR APERTURE ANTENNAS
Power Density/Distance Equations for Fixed-Beam Systems
Near-Field Case. The upper bound on the near-field distance is given
by:
D2
Rnfu - 4X	(B-1)
where
D = diameter of the antenna
X = excitation wavelength.
The term D can be eliminated from Equation B-1 by use of the following
relationships:
d2 = iA = i^e = _g£_
v	itr\	2
v n
A
for	A = —	(B-3)
n
GX2
and	A = ~~	(B-4)
e 4 it
where
A	=	physical area of the antenna
A	«	effective area of the antenna
e
n	*	aperture efficiency (assumed to be 0.5 in the analysis)
G	=	main-beam gain of the antenna (numeric).
B-2

-------
ECAC-CR-82-093
Appendix B
By substitution, the upper bound of the near-field distance can be expressed
as:
G X	G a
r = —— or = ——	(B—5)
nfu	, 2	_ 2
4 it n	2n
for the assumed antenna aperture efficiency of 0.5.
From Reference 8, the on-axis power density Wnf) within the near field
is given as:
4F
W =	n	(B-6)
nr	A
where
P ¦ average transmitter power. (For pulsed emitters, the
average power is the product of peak power and duty cycle.)
The area term A can be eliminated from Equation B-6 by application of the
relationships expressed in Equations B-3 and B-4 with the result that B-6 may
be rewritten as:
4 TIP
W =	(B-7)
nf GX2
Crossover-Field Case. The upper bound distance of the crossover
field (Rcfu) can be expressed as:
2
R . = 0.6	(B-8)
cfu	X
The term D can be eliminated by the use of Equation B-2, so that Rcfu can
be expressed as:
Rcf» ¦ ''V* "	GX	
-------
ECAC-CR-82-093
Appendix B
The power density (Wcf) as a function of distance (R) in the crossover
region can be written ass
cf	nf
where
)
f Rnfu
" Wnf	~T~	(B-10)
R , < R < R _	(B—11)
nfu — - cfu	v '
Distance in the crossover	region (Rcf) as a function of a specified power
density (W) is given by:
- feX
Rcf * \~~W / Rnfu
Far-Field Case. The general equation for far-field power density
(Wff) as a function of distance is:
PG
Wff = 			(B—13)
4ttR
where
R > R .	(B-14)
— cfu
An alternate form of the far-field power density equation in terms of
near-field parameters	and Rnfu) was used in the analysis and is derived
below.
From Equation B-7:
4tt
From Equation B-5:
2
W G\2
(B-15)
GX - 211 Rnfu	(B-16)
B-4

-------
ECAC-CR-82-093
Appendix B
when substituted in Equation B-13, the equation becomes
2 R f 2
w - - = 7~ W ( -SLi. )	(B-17)
ff	4 nf R '
From Equation B-17, distance in the far field (Rff) as a function of
power density is given by:
W „ ^
R,. = r R - ( -7T- )	(B-18)
ff 2 nfu W J
From Equation B-13, the far-field distance equation can be expressed as:
*ff - ^ [ ? >/2	,B"'9)
Power Density/Distance Equations for Scanning Beam Systems
When an aperture antenna is operated in a scanning mode, the average
power density at a point in space illuminated by the main beam of the antenna
is less than that from the main beam of a fixed-beam antenna. Hie change in
power density can be expressed in terms of a scan reduction factor. Because
the antenna beam is not fully formed in the Fresnel region, the scan reduction
factor for the near-field and crossover regions differs from that used for the
far-field region.
The scan reduction factor (S) applicable to the near-field and crossover
regions can be expressed as:
6
S - ^	(B-20)
nc 0
s
B-5

-------
ECAC-CR-82-093	Appendix B
g
0w is an angle factor defined by the segment of a circle, at a given range R,
included in the projection of the antenna aperture. The angle scanned is
defined as 0_. Both 0„ and 0_ are in degrees. Hence:
s	w	s
360 D
e» - -zrs
From the relationships given by Equations B-2, B-3, and B-4, 0W can be
written as:
360 X /G
0» " 	j- 2 .	
-------
ECAC-CR-82-093	Appendix B
The distance 
-------
ECAC-CR-82-093
Appendix b
From Equations B-13 and B-17, this becomes:
0,
PG
W
ffr	.2 . -
4irR * s

or
i- •»< M (tt)
2	(B-32)
e.
where
R ! Rcfu	(B-3 3)
The distance (Rffr) at which a specified power density (W) occurs in the
far field is given by:
PG 9b \ 1y/2
Rffr = 1 4u W 0
s
U	(B-34)
n£ b \
ot 1 ~—"—r~) R„f»
/ 2 W
I ir r
I 4 W
Power Density/Distance Equations for Linear Antennas
The output power for emitter systems using linear antennas is often
expressed in terms of the EIRP. The equations used to express the power
density/distance relationships are written in terms of EIRP.
Near-Field Case. The near-field power density (WN) as a function of
distance can be expressed as:
EIRP „
"» ¦ 7T"c	(B"35>
4trR
B-8

-------
ECAC-CR-82-093	Appendix B
where
Nc = 10 S	(B-36)
Nc is a near-field correction factor for linear antennas^ valid for
0.001 A < R < 0.1 X
By combining Equations B-35 and B-36, the distance (Rjj) at which a
specified power density (W) occurs can be written as:
EIRP
N " 0.4 nWX
Far-Field Case. The equation for power density (Wp) in the far field
as a function of distance is given by:
EIRP	» .
W - 	—	(B-38)
F 4irR
for
R > 0.1 X	(B-39)
The distance (RF) at which a given power density occurs is:
s ¦ (Iff*
^Parker, D., Metropolitan Radiation Hazards# ECAC-PR-73-005, ECAC, Annapolis,
MD, January 1973.
B-9/B-10

-------
ECAC-CR-82-093
Appendix C
APPENDIX C
DATA MANIPULATION PROCEDURES
The data manipulation procedures used in this project are described below
and shown in Figure C-1. Included in the figure are the names of the files
processed in each procedure.
1.	The existing Consolidated Frequency Environmental File (CFEF)
Select Program was used to extract records from the Government Master File
(GMF) and Federal Communications Commission (FCC) File.
2.	The ECAC Environmental Analysis System (EASY) was used to select,
from each assignment record, a single value of frequency, power, duty cycle,
and gain to be used in the analysis. Modules were modified in EASY's Record
Formulation Program to select those values from the files that gave mean value
for a frequency range and maximum values for power, duty cycle, and gain? this
selection procedure is illustrated in Figure C-2.
3.	The EASY Maintenance Program was used to identify each record as
belonging to one of the following categories of emitters:
a.	AM broadcast
b.	FM broadcast
c.	TV broadcast
d.	Civilian fixed-beam radar
e.	Civilian scanning radar
f.	Military fixed-beam radar
g.	Military scanning radar
h.	Satellite earth stations (main beam)
i.	Satellite earth stations (off axis)
j.	Other (10-100 kHz)
k. Other (100.1 kHz-30.561 MHz)
1. Other (30.5611-960.0 MHz)
m. Other (above 960.0 MHz).
C-1

-------
ECAC-CR-82-093
Appendix c
C
START
Files Processed
SELECT RECORDS
FROM ECAC
DATA BASE
TRANSFORM RECORDS
KEEPING ONLY
MAXIMUM POWER,
GAIN, AND DUTY
CYCLE FOR EACH
RECORD
(SEE FIGURE C-2)
USE ANALYTICAL
EQUATIONS & CREATE
TAPE OF EPA FOR-
MATTED UNCLASSI-
FIED RECORDS
(SEE FIGURE C-3)
1	FCC, GMF
2	BROADCAST, RADAR,
EARTH STATIONS, OTHER
3	BROADCAST, RADAR,
EARTH STATIONS. OTHER
4	BROADCAST, RADAR,
EARTH STATIONS (MAIN BEAM)
EARTH STATIONS (OFF AXIS),
OTHER
5	AM BROADCAST, FM
BROADCAST, TV BROADCAST,
FIXED-BEAM CIVILIAN RADAR,
SCANNING CIVILIAN RADAR,
FIXED-BEAM MILITARY RADAR,
SCANNED MILITARY RADAR,
EARTH STATIONS (MAIN BEAM) ,
EARTH STATIONS (OFF AXIS) ,
OTHER (10-100 kHz),
OTHER (100.1 kHz-30.561 MHz),
OTHER (30.5611-960.0 MHz)
OTHER (ABOVE 960.0 MHz)
6	SAME AS 5.
Figure C-1. Flowchart for the data manipulation procedures.
C-2

-------
ECAC-CR-82-093	Appendix C
Figure C-2. Flowchart for multivalued data recovery.
C-3

-------
ECAC-CR-82-093
Appendix c
Note that each satellite earth station record has been duplicated
to create separate categories for main-beam and off-axis cases.
4.	Modules of the EASY Maintenance Program were modified and other
modules were created to perform the power density/distance analysis, store the
resulting statistics on disk, and create the tape file containing the
unclassified EPA Master Data Base (see Figure C-3).
To perform the analysis, the data in the records was mapped into an
array. TV audio records and records of radars with low-gain antennas were
bypassed and data recovery and unit conversions were made as shown in Figure
C-4. Note that power listed in TV video records is incremented by 20% to
compensate for the TV audio power. Other recovery techniques are discussed in
APPENDIX A. Figures C-5 and C-6 are flowcharts of the power density/distance
analysis for emitters with linear antennas (gains of 10 dBi or less) and those
with aperture antennas (gains of greater than 10 dBi). Figure C-6 is expanded
in Figures C-7 through C-10 to show the techniques used for power density and
distance calculations for both fixed-beam and scanning aperture antennas.
Note that in the power density calculations using off-axis antenna gains, the
resulting power densities were reduced by 20 dB and that in the distance
calculations using off-axis antenna gains, the specified power densities are
increased by 20 dB. Also note that distances are not computed for off-axis
power densities in the near field.
The record output to the tape contained data from the original ECAC data
base and the calculated power density and distance values. No recovered
values were included on the tape.
5.	A new program was written to print the contents of the tape file
on paper. Samples of the print are contained in APPENDIX E.
6.	A new program was written to draw the histograms from the
statistics file generated by procedure 4 (see Figure C-3). Samples of the
histograms are contained in Section 2 of this report.
C-4

-------
ECAC-CR-82-093
3
Appendix C
OBTAIN RECORD
AND MAP DATA
INTO ARRAY
RECOVER DATA
(SEE FIGURE C-4)
MAKE CALCULATIONS
(SEE FIGURES
g-s * c-6>
NO

OUTP
TO
TAP
JT
E


RECORDS >-
NO
*
OUTPUT
FILE TO
TATISTICJ
DISK

*
PRINT I
COUN1
(ECORDS
'ERS
	9

( " )
Figure C-3. Flowchart for the power density analysis and tape
file creation.
C-5

-------
ECAC-CR-82-093	Appendix C
Figure C-4. Flowchart for the data conversions and recoveries.
C-6

-------
ECAC-CR-82-093
Appendix C
DIST
PDEN
ARRAY OF EIGHT DISTANCES
ARRAY OF SEVEN POWER DENSITIES
V
I START	J

'
CALCULATE POWER
DENSITY AND
DISTANCE FOR NEAR
FIELD BOUNDARY
1*1; J»1
CALCULATE POWER
DENSITY USING
FAR-FIELD
EQUATION
CALCULATE POWER
DENSITY USING
NEAR-FIELD
EQUATION
Figure C-5.
Flowchart for the calculation of power density and
distance for emitters with linear antennas*
C-7

-------
ECAC-CR-82-093
Appendix c
Figure C-6. Flowchart for the calculation of power densities
and distances for emitters with aperture antennas.
C-8

-------
ECAC-CR-82-093
Appendix C
NFDIST-NEAR FIELD BOUNDARY
NFPDEN-POWEF DENSITY IN THE NEAR
FIELD
CFDIST-CROSS OVER FIELD UPPER
BOUNDARY
IS
OFF-AXIS
NO
Figure C-7. Flowchart for the calculation of power densities
for emitters with fixed-beam aperture antennas.
C-9

-------
ECAC-CR-82-093
Appendix
Figure C-8.
Flowchart for the calculation of distances from
emitters with fixed-beam aperture antennas.
C-10

-------
ECAC-CR-82-093
Appendix C
POWER DENSITY-
NEAR-FIELD
POWER DENSITY
WITH SCAN REDUCT-
ION FACTOR
0^
POWER DENSITY-

CROSSOVER FIELD
YES
e	<
POWER DENSITY
WITH SCAN REDUC-
TION FACTOR FOR

GIVEN DISTANCE

NFDIST-NEAR-FIELD BOUNDARY
CFDIST-CROSSOVER FIELD UPPER
BOUNDARY
POWER DENSITY-
FAR-FIELD POWER
DENSITY WITH SCAN
REDUCTION FACTOR
FOR GIVEN
DISTANCE	
Figure C-9. Flowchart for the calculation of power densities for
emitters with scanning antennas.
C-11

-------
ECAC-CR-82-093
Appendix
NFPDEN-POWER DENSITY IN THE NEARAFIELD
CFPDEN-POWER DENSITY AT THE CROSS-
OVER FIELD UPPER BOUNDARY
31STANCE=FAR HFIELD
DISTANCE FOR	^
" 3IVEN POWER DENSITY
iflTH SCAN REDUCTION
TACTOR

DISTANCE=CROSS-

OVER DISTANCE FOR
YES
f (
GIVEN POWER

DENSITY WITH SCAN

REDUCTION FACTOR

Figure C-10. Flowchart for the calculation of distances from
emitters with scanning antennas.
C-12

-------
ECAC-CR-82-093
Appendix D
APPENDIX D
FORMAT AND CONTENTS FOR EPA MASTER DATA BASE
ECAC has provided the EPA with an unclassified Master Data Base file on
magnetic tape and in hard copy. The format and content of this file are
discussed below:
1.	Data format for magnetic tape
a.	9-track
b.	1600 bits per inch
c.	Oontains no ANSI labels
d.	EBCDIC formatted characters capable of being directly read by an
IBM computet or by a UNIVAC conqputer using the quarter-word mode.
e.	Each record is 524 characters (or 131 words) in length with one
record per block.
2.	Data format for hard copy
The data format for the hard-copy data base is illustrated in Figure
D-1.
3.	Record content
a.	TAHLE D-1 provides the details of the records in the file.
b.	Each field was assigned a sequential number.
c.	Where applicable, the corresponding field number for the field in
the ECAC Consolidated Frequency Environment File (CFEF) record is furnished.
Values in fields without CFEF record numbers were calculated from the file
data and do not exist in the CFEF.
d.	When data for a field is missing, the field was blank filled.
e.	The tape record was preblanked prior to data entry.
D-1

-------
RECORO / FREQUENCY /
LOCATION IkFORMAUON
LCCATION / EQUIPPENT /
AKTENNA INFORMATION
ANTENNA
INFORMATION
ANTENNA INFO/
CALC. DATA
ROTATIONAL
REOUCT-FACTOR
NONTH XX* XXXX PAGE XXXX
POUER DENSITIES OISTANCES
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xxxxxxxxxxxx
(58 =
XXXXXXXX
843 =
xxxxxx
¦ 51 =
xxxxxxxxxxxx


SEO NO.
«Q1 =	XXXXXX 102= X
(03=	XXXXXXXXXXX
104=	XXXXXXXXXXX
(05=	xxxxxxxxxxxxxx
106=	XXXX
107=	xxxxxxxxxxxxxxxxxx
¦08=	XXXXXXX »69 = XXXXXXXX *19= XXXXX
110=	XXXXXX
¦11= XXXXXXXXXXXXXXXXXX
(13=	XXXXXXXXX 112= X
¦14= XXXXXXXXX
¦13=	XXXXXX *16= XXXXXX
¦17= XXXXXXXXXXXXXXXXXXXXX
¦18= xxxxxxxxxxxxxxxxxx
¦28= XXXXX
¦20=	XXXXX	*29= XXXX
¦21=	X 122= X «30 = XXXX
¦23=	XXX	¦31= XXX
¦ 24 = XXX	*32 = XXXXXXXXX
¦25=	XXXX	<33= XXXXXX
¦26= XXX	134= XXXXXXX
¦27=	XXX	«3S= XXXXXXXX
¦ 36=
XXXXXX
¦ 44 =
XXXXXXXXXXXX
(52 =
XXXXXXXX
¦ 37;
xxxxxx
¦ 45 =
xxxxxxxxxxxx
(53=
XX xxxxxx
¦ 38=
xxxxxx
¦ 46 =
xxxxxxxxxxxx
(54 =
XXXXXXXX
¦ 39=
xxxxxx
¦ 47 =
xxxxxxxxxxxx
(55 =
XXXXXXXX
¦ 40 =
xxxxxx
(4tt =
xxxxxxxxxxxx
¦ 56 =
XXXXXXXX
¦ 41 =
xxxxxx
• 49=
xxxxxxxxxxxx
¦ 57 =
XXX XXXXX
¦ 42 =
xxxxxx
¦ 50 =
xxxxxxxxxxxx
¦ 58 =
xxxxxxxx
¦ 43=
xxxxxx
¦ 51 =
xxxxxxxxxxxx


SEO AO. XXXXXX
¦ 08 =
XXXXXXX 109= XXXXXXXX
¦ 19 =
XXXXX

¦28= XXXXX
¦ 36=
XXXXXX
¦ 44 =
XXXXXXXXXXXX
(S2=
XXXXXXXX

¦ 10 =
xxxxxx
¦ 20 =
XXXXX

•29= XXXX
¦ 37 =
xxxxxx
¦ 45=
XXXXXXXXXXXX
(53=
xxxxxxxx
¦01= XXXXXX (02= X
¦ 11=
xxxxxxxxxxxxxxxxxx
¦ 21 =
X >22 =
x
¦30= XXXX
¦ 38=
xxxxxx
(46 =
xxxxxxxxxxxx
(54 =
XXXXXXXX
¦03= XXXXXXXXXXX
¦ 13 =
XXXXXXXXX 112= X
¦ 23 =
XXX

¦31= XXX
• 39=
xxxxxx
(47 =
xxxxxxxxxxxx
(55 =
XXXXXXXX
¦04= XXXXXXXXXXX
¦ 14 =
XXXXXXXXX
(24 =
xxx

¦ 32= XXXXXXXXX
¦ 40 =
xxxxxx
(48 =
xxxxxxxxxxxx
(56 =
XXXXXXXX
¦05= XXXXXXXXXXXXXX
¦ 15=
XXXXXX 116= xxxxxx
(25 =
XXXX

¦33= XXXXXX
¦ 41 =
xxxxxx
¦ 49 =
xxxxxxxxxxxx
(57 =
XXXXXXXX
¦06= XXXX
¦ 17 =
XXXXXXXXXXXXXXXXXXXXX
(26=
xxx

¦34= XXXXXXX
¦ 42 =
xxxxxx
(50 =
xxxxxxxxxxxx
(58 =
XXXXXXXX
(07= xxxxxxxxxxxxxxxxxx
¦ 18 =
xxxxxxxxxxxxxxxxxx
(27 =
xxx

¦35= XXXXXXXX
¦ 43=
xxxxxx
(51 =
xxxxxxxxxxxx


SEO NO. XXXXXX
¦ 08 =
XXXXXXX (119= xxxxxlxx
(19 =
XXXXX

¦28= XXXXX
¦ 36=
xxxxxx
¦ 44 =
xxxxxxxxxxxx
¦ 52=
XXXXXXXX

¦ ie =
xxxxxx
(20 =
XXXXX

¦29= XXXX
• 37 =
xxxxxx
¦ 45 =
xxxxxxxxxxxx
(53 =
XXXXXXXX
¦01= XXXXXX 1023 X
¦ 11=
xxxxxxxxxxxxxxxxxx
(21 =
X (22*
X
¦30= XXXX
¦ 38 =
xxxxxx
¦ 46 =
xxxxxxxxxxxx
(54 =
XXXXXXXX
¦03= XXXXXXXXXXX
¦ 13 =
XXXXXXXXX (12= X
(23=
xxx

¦31= XXX
¦ 39=
xxxxxx
¦ 47 =
xxxxxxxxxxxx
(55 =
XXXXXXXX
¦04= XXXXXXXXXXX
¦ 14 =
XXXXXXXXX
(24 =
xxx

¦32= XXXXXXXXX
• 40 =
xxxxxx
¦ 48 =
xxxxxxxxxxxx
(5b =
XXXXXXXX
¦05= xxxxxxxxxxxxxx
¦ 15 =
XXXXXX <16= xxxxxx
(25 =
XXXX

¦33= XXXXXX
• 41 =
xxxxxx
¦ 49 =
xxxxxxxxxxxx
¦ 57 =
XXXXX XXX
¦06= XXXX
¦ 17 =
XXXXXXXXXXXXXXXXXXXXX
(26 =
xxx

¦34= XXXXXXX
• 42 =
xxxxxx
¦ 50 =
xxxxxxxxxxxx
(58 =
XXXXXXXX
¦07= xxxxxxxxxxxxxxxxxx
¦ 18 =
XXXXXXXXXXXXXXXXXX
¦ 27 =
xxx

¦35= XXXXXXXX
• 43=
xxxxxx
¦ 51 =
xxxxxxxxxxxx


Figure D-l. Data format for hard-copy data base.

-------
ECAC-CR-82-093
Appendix D
TABLE D-1
FIELD DEFINITION FOR EPA RECORD
(Page 1 of 4)
EPA
Record
Field
Number
ECAC
Record
Field
Number
Field Title
Length
(Char.)
Field
Location
1
1001
ECAC Record ID
6
1-6
2

Type of record (AM broadcast,
FM broadcast, TV broadcast,
composite broadcast, fixed beam
civilian radar, etc.)
1
9
3
1005
Frequency, lower limit or
discrete value
11
13-23
4
1006
Frequency, upper limit for
a range
11
25-35
5
3008
TX call sign
14
3 7-50
6
3001
TX state/country
4
53-56
7
3002
TX city/base
18
57-74
8
3005
TX. latitude
7
77-83
9
3006
TX longitude
8
85-92
10
2001
Operating agency
6
93-98
11
3201
TX system nomenclature
18
101-118
12
3104
Power type code
1
121
13
3103
TX power, lower limit or
discrete value (kw)
9
125-133
14
3109
TX power, upper limit for
a range (kW)
9
137-145
15
3211
Pulse width selected from
CFEF record for use in the
analysis (microseconds)
6
149-154
16
3221
Pulse repetition rate selected
from CFEF record for use in
the analysis (pps)
6
157-162
D-3

-------
ECAC-CR-
82-093
Appendix D
TABLE D-1
(Page 2 of 4)
EPA
Record
Field
Number
ECAC
Record
Field
Number
Field Title
Length
(Char.)
Field
Location
17
3301
TX antenna type
21
165-185
18
3302
TX antenna nomenclature
18
189-206
19
3303
TX antenna gain (dBi)
5
2 09-213
20
3305
TX antenna height above ground
(feet)
5
217-221
21
3307
TX antenna motion type code
1
225
22
3313
TX antenna polarization code
1
229
23
3308
TX antenna fixed azimuth
from north (degrees)
3
233-235
24
3318
First satellite TX azimuth
angle (degrees)
3
237-239
25
3327
Second satellite TX azimuth
angle (degrees)
4
241-244
26
3309
TX antenna horizontal arc scanned
- from (degrees)
3
245-247
27
3310
TX antenna horizontal arc scanned
- to (degrees)
3
249-251
28
3311
TX antenna horizontal motion rate
(RPM)
5
253-257
29
3314
TX antenna horizontal beam width
(degrees)
4
261-264
30
3315
TX antenna vertical beam width
(degrees)
4
265-268
31
3312
TX antenna elevation angle
above horizontal (degrees)
3
269-271
32

9
On-axis power density (mW/cnr)
at the near-field boundary
distance
9
273-281
D-4

-------
ECAC-CR-82-093
Appendix D
TABLE D-1
(Page 3 of 4)
EPA
Record
Field
Number
ECAC
Record
Field
Number
Field Title
Length
(Char.)
Field
Location
33
~
Near-field boundary distance
(meters) derived from frequency
and gain
6
285-290
34
	
Wavelength (meters) derived from
frequency
8
293-300
35
	
Physical antenna area (meters2)
derived from gain
8
301-308
36
	
Rotation reductional factor
(unitless) at 100 meters
6
309-314
37
	
Rotation reductional factor
(unitless) at 200 meters
6
317-322
38
	
Rotation reductional factor
(unitless) at 500 meters
6
325-330
39
	
Rotation reductional factor
(unitless) at 1 kilometer
6
333-338
40
	
Rotation reductional factor
(unitless) at 2 kilometers
6
341-346
41
	
Rotation reductional factor
(unitless) at 5 kilometers
6
349-354
42
—-
Rotation reductional factor
(unitless) at 10 kilometers
6
357-362
43
—-
Rotation reductional factor
(unitless) at 20 kilometers
6
365-370
44
	
Power density (mW/cm2) at 100
meters
12
373-384
45
	
Power density (mW/cm2) at 200
meters
12
385-396
46
—
Power density (mW/cm2) at 500
meters
12
397-408
D-5

-------
ECAC-CR-82-093
Appendix Q
TABLE D-1
(Page 4 of 4)
EPA
Record
Field
Number
ECAC
Record
Field
Number
Field Title
Length
(Char.)
Field
Location
47
	
Power density (mW/cm2) at
1 kilometer
12
409-420
48
	
Power density (mW/cm2) at
2 kilometers
12
421-432
49
	
Power density (mW/cm2) at
5 kilometers
12
433-444
50
	
Power density (mW/cm2) at
10 kilometers
12
445-456
51
	
Power density (mW/cm2) at
20 kilometers
12
457-468
52
	
Distance (meters) for power
dens ity 0.01 mW/cm
8
469-476
53
	
Distance (meters) for power
density 0.025 mW/cm^
8
477-484
54
	
Distance (meters) for power
density 0.05 mW/cm^
8
485-492
55
	
Distance (meters) for power
density 0.1 mW/cm2
8
493-500
56
	
Distance (meters) for power
density 0.5 mW/cm
8
501-508
57
	
Distance (meters) for power
density 1.0 mW/cm^
8
509-516
58
— —
Distance (meters) for power
density 10.0 mW/cm^
8
517-524
D-6

-------
ECAC-CR-82-093
Appendix E
APPENDIX E
SAMPLE MASTER DATA BASE PRINT
Figures E-1 through E-4 are sample Master Data Base prints for the four
main categories of emitters — broadcast stations, radars, earth stations, and
others. Also supplied, as Figure E-5, is a table of contents that will be
included with each category in the printout.
E-1

-------
fctCORD / FREQUENCY /
LOCATION / CQUTPHENI /
NTcNHl
ANTENNA INF»/ ROTATIONAL
JUNE It, Itlt
PA6f J1
LOCATION iNfORNAlIOl
ANTENNA INFORMATION
INFORMATION
CALC.
DAT*
R£Ol»tT-f *cTO»
PfUCR densities
DISTANCES
SCO NO. OOJ181
•08 =
932729N
•09= 1D32839U
¦ 19 =

¦ 28 =

• 36 =
• 99 =
.Doll
¦ 52 =
29.3

•10 =
rcc

¦ 20=

¦ 29=

¦ 37=
¦ 95-
.000315
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9.7
¦ 01= ?&ier>i *o?= a
•11 =


¦ 21 =
¦ 22 =
¦ 30=

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• 96=
.OOOOSq
¦59 =
9.9
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¦ 13 =
O.S
112= N
¦ 23 =

(31 =

• 39 =
•97=
.000011
¦ 55 =
2.9
• G*:
• 1*1 =

-	
¦ 24 =

¦ 32 =
- .00*1
¦ *o= 	
¦ 98=-
—.0 0 0 00315
¦ 56 =

• S5: HORN
¦15 =

816=
¦ 25 =

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51.7
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IOC ZtitH
•17 =


(26 =

¦ 19 =
SH.24
¦ *2=
• 50=
.00000013
¦ 58 =

HOT SPRINGS
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¦ 27 =

¦ 35 =

¦ 93 =
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.0000000315


SCU NO. C>Cul 82
•38 =
359990N
(09= 0893919U
• 19 =

¦ 28=

¦ 56=
¦ 99 =
.0025
¦ S2 =
98.7

• 10 =
FCC

• 20 =
...
¦ 29=

137=
¦ 95=
.000629 -
¦53 =
19. S
• 01: 2S23*F *02= A
• 11 =


¦ 21 =
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¦ 30=

¦ 38 =
• 96=
• OOOlol
¦S* =
9.7
• 33 = 58C
•13 =

• 12= It
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• 39 =
• 97=
.000325
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9.9
• 0« =
il«:


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.009*
¦ 90 =
¦ 98 =
.00000629
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1.0
»(i5- wort
•15 =

(It:
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SI.7
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¦ 99=
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• 57 =

• 06 = UNN
•17 =


¦ 26=

• 19 =
SU.it
¦ 92=
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• 0000002S
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• 07= 5oC KWOOO
¦ 18 =

" " ""
• 27=
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¦ 35=

¦ 93=
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see no. aoJia)
• 38 =
333200N
• 09= 10I9919U
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29.3

• 10=
FCC

¦ 20=

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¦ 37 =
¦ 95 =
.000315
• 53 =
9.7
ID|: 2S1 ePO *02= A
• 11 =


¦ 21 =
¦ 22 =
¦ 30=

¦ J8 =
¦ 96=
.0000 50
¦ 59 =
9.9
• 31: 58 0
• 13 =
0.5
¦ 12= N
¦ 21 =

¦ 31 =

• 39 =
¦ 97 =
.000013
¦ 55 =
2.9
• I*:
«1»:


I2»:

¦ 32 =
.00*7
¦ 90=
¦ 98 =
.00000315
¦ Si =

»0i = MKL6
•15 =

lib:
¦ 25=

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SI. 7
¦ «! =
¦ 99 =
.000 00050
¦ 57 =

¦ 06= 1£»
•17 =


• 26=

• 11:
511.2*
¦ 92 =
¦ 50=
.00000013
¦ 5 8 =

¦ 07: LlRBOCK
• 18 =


¦ 27=

¦ 35 =

¦ 93 =
¦ 51 =
.00 0 0 0 00315


sco no. coats*
•38 =
369S10N
•09= 0775I99U
¦ 19 =

¦ 28 =

¦ 36 =
¦ 99 =
.0013
¦ 52 =
29.3

•10 =
FCC

¦ 23 =

¦ 29=

¦ 37=
¦ 95=
.000315
¦ 53 =
9.7
(01: 2S23E2 (02= A
• 11 =


¦ 21 =
¦ 22 =
¦ 30=

¦ 38 =
¦ 96=
.000 050
¦ 59 =
9.9
• 03: 540
•13 =
O.S
• 12= H
¦ 23 =

¦ 31 =

¦ 39=
(97=
• 000013
¦ 55 =
2.9
• O*:
• 1 9 —


¦ 29 =

• 32 =
.00*7
¦ 90=
(98=
.00000315
¦ 56 =

• C5: wlF S
• 15 =

• 16=
¦ 25 =

• 33 =
SI.7
¦ «l =
(99 =
.00000050
¦ 57 =

¦ 06 : V*
• 17 =


¦ 26=

¦ 3» =
SIT.29
¦ 92 =
(50=
.00000013
¦58 =

•07: LAURFkCCVILLC
• 18 =


• 27=

• 35 =

¦ 93 =
(51 =
.00 0 0 0 003IS


SCO NO. 000165
• 38 =
939925N
• 09= 091122 1U
¦ 1» =

• 28 =

¦ 36 =
199 =
.0126
¦ 52 =
112.2

• 13 =
FCC

• 20 =

• 29=

¦ 37 =
• 95 =
.0 03 1 96
¦ S 3 =
70.9
•Ot: 2S2 3|J *02: A
• 11 =


¦ 21 =
¦ 22 =
¦ 30=

¦ 38 =
• 96=
.000503
¦ 59 =
98.7
• 03: 5o0
• 13=
5
• 12= M
¦ 23 =

• 31 =

¦ 39 =
• 97 =
.000126
¦55 =
29.3
•
•19 =


• 24 =

• 32 =
.0970
¦ 90=
• 98 =
.00003196
¦56 =
9.9
• OS: UrIV
• 15 =

• 16 =
¦ 25 =

•33 =
SI.7
¦ 91 =
• 99 =
.00000503
¦ 57 =
2.9
• Ob: WIS
• 17 =


¦ 26 =

• 39 =
517.29
¦ 92 =
• 50=
.0 0 0 00 1 26
¦ 58 =

•CI: LA CRUSSC
• 18 =


127 =

• 35 =

¦ 93 =
• 51 =
.0000003196


SCO NO. 0001S6
•38 =
939925N
•09= 09I122IU
¦ 19 =

¦ 28 =

¦ 36=
• 99 =
.0025
¦ 52 =
98.7

• 10 =
FCC

• 20 =

¦ 29 =

¦ 37 =
• 95 =
.000629
¦ 53 =
19.5
• Ql: 2S23AK »02 = A
• 11 =


¦ 21 =
¦ 22 =
¦ 30=

¦ 38 =
¦ 96=
.000101
¦59 =
9.7
• 03: 5b0
• 13 =

• 12= 1*
¦ 23 =

• 31 =

¦ 39=
¦ 97 =
• OC002S
¦ 55 =
9.9
• C«:
IIC


¦ 29 =

• 32 =
.0099
¦ 9 0 =
¦ 98 =
.00000629
¦ S6C
1.0
105: UhTV
• 15 =

• 16=
(25 =

• 33 =
SI.7
¦ 91 =
¦ 99 =
.00000101
¦ 57 =

• Cfc: WIS
•17 =


¦ 26 =

• 3* =
SI 7.29
• 92 =
¦ 50=
.00000025
¦58 =

•07: LA CROSSE
•18 =


¦ 27 =

• 35 =

• 93 =
¦ 51 =
.0000000629


Figure E-1. Sample
EPA Master
Data
Base print - AM broadcast.

-------
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IOC* HON IhfllRHlllO*
it»i no. orjisi
Locmtii t mmpheni
wKiit iNroantriON
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•	17 =
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¦ 16= 7.2*
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121=
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18.3556
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•09= 06939SIV
• 19=

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• 20=

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• 21 =

• 31 =

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• 55 =
9.9
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• 29 =

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18.3556
• «0 =
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•56=
9.2
• CS = PlN
•15 =
3.S
• 16= 7.2*
*2?=

¦ 33=
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• 99=
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9*2=
• 50=
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•58 =
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•09= 0871956W
• 19 =

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¦ 20 =

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118 =


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it a no. bnoit9
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125 =
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SES HO. QCSliS
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¦ 99 =
• S2 =


¦ 10 =
Ml

• 23 =

• 29 =

¦ 17 =
~ MS=			
•51 =

• 31= *02= C
•11 =


• 21 =
¦ 22=
• 30=

¦ !•=
«U=
•59 =

¦ 03= '1016
rl ] =
15
¦ 1?= 9
¦ 21 =

• 31 =

¦ 39 =
¦ 9 2=
•55 =

90* =
>19 =


¦ 29=

¦32 =

111:'
- " ¦*•=
• 56 =

¦OS: CIU
l|S =

¦ 16=
• 25 =

• IS:

¦ 11 =
|H =
¦ 57 =

• ; TMIO
•17 =


¦ ?« =

¦ 39 =
.30
¦ 92 =
• 50=
• 58 =

• Cl = UCtk^llIM
• 11 =


|2T=

¦15 =
9.1369
¦ 91=
— «si=	












»*»«*»«»•
SCO NO. OROIS6
•08 =
382010N
•09= 0772111U
• 17 =

¦ 28 =

• 16 =
¦99= .0009
•52 =
29.8

•1C =
F**

• 20 =

«?» =

837 =
•95= i000223
• 51 =
IB.9
• 01= IPOMfH 802= C
• 11 =


• 21 =
¦ 22 =
¦ 30=

• 38 =
¦ 96= .000 0 36
•59 =
13.1
¦ 31= tt|016
•11 =
15
¦ 12= P
• 21 =

• 11 =

¦ 39 =
¦ 97= .(100009
• 55 =
9.9
• r.«=
•19 =


• 29=

• 12=
IB.5556
• 10=
¦98= .00000221
• 56 =
9.2
• 05= fRW
•15 =
3.5
• 16= 7.2*
• 25 =

¦ 33 =
« .9
• 91 =
¦99= .00000036
• 57 =
1.0
• 06= M
•17 =


• 26 =

• 39 =
.10
• 92 =
¦50= .00000009
• 58 =
.1
• Cf= POO out
•18 =


• 27 =

¦ 35 =
9.1389
• 93 =
• 51= -.00 0 0 0 00 2 23



Figure
E—2 .
Sample EPA Master
Data
Base print -
civilian
fixed-beam radar.



-------
JUNC It, I 982	PA6E 2
krcoor / fnecuencv / location / equipment / antenna	antenna info/ r&tational	,
locai ion iNruRN«iio< anienna information	information calc. data 'tou;i-factor POUCR OCNSITIFS DISTANCES
UU NC. uCCOOT
¦OS:
*10118N
¦ C9: 08511 1«U
¦ l» =

¦ 28 =

• 16 =
• * * =
.0716
• 52 =
267.6

¦10=
rcc

• ?0 =
42
8 ?9 =

837=
• 85=
.017905
¦ 53 =
169.1
Idi: 10?= C
¦ 11 =


• 21:
¦ ?2r
• 10 =

• 38 =
886=
.0 02 865
¦58 =
119.7
»CJ: tAl.CH
813=
90
• 12= ft
121=

811 =

839 =
887 =
.P00 716
855 =
B*. 6
bo*=
•1 * =


8?* =

• 1?= 1
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• *0 =
888 =
• 00017905
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17.8
»cs- Hsrssj
•15:

116=
• ?5 =

• 33 =
.T
8*1 =
¦ 89=
.00002865
• 57 =
26.8
fc!?6 = I*PA
¦ 17:


• 26 =

• 18 =
6.96
»»2 =
• 50 =
.00000716
¦58 =
8.5
• njr ro^T KAVI.E
•ia =


827=

• 35 =

8 81 =
• 51 =
.0000017905


SCO NO. LOuOoB
•3):
*10339N
•09= 08SQSS6U
819 =

,?8 =

• 56:
8m-
.0697
• »2 =
2** . 1

A|0:
FCC

820 =
0
• ?9 =

837 =
885 =
.018921
• 53 =
1 5* . 5
tot: ;f«vii io?: c
¦11:


821 =
8 22-
• 10=

• 38 =
886 =
.002387
• 58 =
109. 1
• 01=
¦ 11:
75
¦ 1?: R
821 =

• *1 =

¦ J9 =
8*7=
• 000 5 9 7
• 55 =
77.1
• r.«»:
¦I*:


828 =

»j?= :
1231.8669
• to=
888 =
.0001*9?!
•56 =
3*.5
azs= Ktcfr.i
¦IS:

¦ 16=
US:

811 =
.1
8*1 =
889 =
.000 02 1ST
•57 =
' 2* .8
A 06* IS1A
•17 =


8?6 =

838 =
6.«6
812 =
850=
.00000597
• 58 =
7.7
111:
¦18:


827=

835 =

¦ A3:
851 =
.0000018921


SrQ NO. l.CDQu'
¦38:
8010S1N
•09: 08819?8M
8l«:

¦28-

• 16 =
18* =
.0318
• 52 =
178.*

¦10:
FCC

820 =
0
¦ ?9 =

¦ 37=
• 85 =
.007958
•5 J =
112.8
»0l: 2uMPI *02- I
¦ li:


821 =
822 =
810=

• 38 =
• *6 =
.001273
•Ss =
79*8
A n3 = M*3.1<:
¦13:
*0
• 12= R
821=

811 =

8 39:
• 87=
.000118
•55 =
56.*
• On;
¦1 * :


• ?*:

• 32 =
857.6056
¦ *0=
• *8 =
~ .000079S8
• S6 =
25.2
¦ OS- fSHdltb
•15 =

816=
825 =

831 =
.7
¦ 11:
• 89 =
.00001273
¦ 57 =
17.8
AC6 = IlL
¦17:


• 26 =

• 38 =
6.96
• *2=
8S0 =
.0 0 0 00118
• 58 =
5.6
• ri:
•ia=


827 =

835 =

ml:
851 =
.000 0 0 07 958


SCJ N?. LrJLl0
AO 6 =
*0SSOON
•09= 0902000W
• 19 =

• ?8 =

• 16 =
¦ **:
.0617
•52 =
252.1

AlO:
FCC

820 =
0
8?9 =

• 37:
• 85=
.015916
• 51 =
159.6
• 01 = 9«S *02 - E
¦11:


• 21 =
822 =
8*0=

¦ 38:
¦ 86 =
.002586
• 58 =
112.8
¦ 0 j: "*1.1*
¦I J :
80
¦ 12 = R
823:

• 11 =

• 39 =
¦*7=
.000617
• 55 =
79.8
• ~.* =
¦1 * :


82*1= '

83?:
1116.8US
• 13 =
888 =
.00015916
¦ 56 =
35.7
• rs: Kki'519
•15:

• 16=
825 =

• 31 =
.7
¦ 81 =
8*9 =
.000025*6
¦57 =
25.2
¦ 5t: ul
¦17:


• 26:

• 38 =
6.95
M2 =
¦ 50 =
.00000617
¦ 58 =
8.0
¦ 07:
¦18:


• 27 =

• 35:

• A3:
851 =
.0000015916


sro nt. crcon
UK:
*20I36N
•09: 08*2808*
• 19:

• 28 =

• 1 6 =
¦ ** =
.119*
• 52 =
1*5.5

•in:
FCC

• 20 =
2S
• 29 =

• 37=
885 =
.029882
¦ 51 =
218.5
*C|: ?&l 7LR AO? = E
¦11 =


• 21 =
¦ ?2=
• 10=

• 18 =
1*6 =
.00*775
•58 =
15*. 5
• ,1J: P*!.l*
¦11:
ISC
81?: R
821 =

• 11 =

• 39 = ~
• 87 =
.00119*
• 55 =
109.3
I0«=
¦1*:


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• 1? =
2868.lo'O
• *0 =
¦ 88 =
.000 298*2
• 56 =
*8.9
ACS: KJC 9 j J
¦IS:

• 16=
• 25:

• 11 =
.7
• A 1 =
¦ *9r
.0000*775
857 =
3*.5
• 76: KJrH
•17:


826:

• 3* =
6.95
M2 =
¦ 50=
.00001 19*
• 58 =
10.9
¦ 31:
¦18:


• 27:

¦35 =

MJ:
¦ 51 =
.00000298*2


iCa NO. DOuOl?
¦08 :
801*1S»<
•09= 0i9bP«SU
»!» =

¦ ?¦ =

• 36:
• ** =
.0398
• 5? =
199.5

• 10:
FCC

• 20:

• 29=

• 37=
¦ 85 =
• C09 9 8 7
•53 =
126.2
AO): 2h? 70S 10?: E
• II:


• 21:
822 =
• 10=

• 38 =
¦ 8 6=
.001592
• 5* =
89.2
«n;r
¦15 =
SO
• 1?: R
• 2 J:

• 11 =

• 19 =
¦ 87 =
.000198
• 55 =
63.1
• c*=
¦l«i =


• 2*:

• 1?:
832.7171
• •0 =
¦ 86 =
.03009987
•56 =
28.?
ADS: US"-®?*
•15:

• 16=
• 25 =

811 =
.7
• 81 =
889 =
.00001592
• 57 =
19.9
¦ 06: IlL
•17 =


• 26 =

• 38 =
6.91
• 82:
8 S0:
.00000398
• 58 =
6 . 3
• 07:
• 18 =


• 27=

• 35 =

*83 =
¦ 51 =
.00000099*7


Figure E-3. Sample EPA Master
Data Base print -
earth station main beam.

-------
JUfcE 18( 1982
PACE
RCCORO / FREOUENCV /
LCCAT lQk UFORMIION
LCCATIOK / EQUIPMENT /
AMENM INFORMATICk
ANTENNA
INFORMATION
ANTENNA INFO/
CALC. DATA
ROTATIONAL
REDUCT-F ACTOR
41
POWER DENSITIES DISTANCES
SEQ NC. 000241 - 	 *0«=
110=
101= 20C8UK 102= *	111=
• 03= M10S55	- - *13=
104= C1170 0	*14 =
*05= KCiXLC	*15=
106= CAL	*17=
107= EL SEEUNOO	<18=
335542N *09= 1182341W
FCC
2.8 	 812= P
116=
<19=
¦	20 =
¦	21 =
123=
• 24=
125 =
¦	26=
127=
122 =
-	(28=-
¦29=
(30=
-	(31 =
¦	32 =
¦	33 =
¦	34= -
*35=
75.2107
89.3
	,0J-
7.4815
-¦36a
¦	37=
*38=
-¦39=
(40 =
(41 =
¦	42=
¦	43=
— ¦44=—
	67.1910
*52=
12176.4
*4 5=
33.595491
*53=
77C1.0
*4£=
5.930611
• 54=
5445.5
— *4 7 = —
	1.482653
*55=
3 £50 .5
¦ 48 =
.37066322
• 56=
1722.0
(4 5=
.05930611
• 57=
1217.6
-(50=—
-.01482653
• 58 =
365.1
(51 =
.0037066322


- «44"
1168.8566
• 52=
50965.8
¦ 45=
584.428299
• 53=
32246.2
¦ 46 =
103.982012
*54=
22.601.5
— «4 7=—
— 25.995503
• 55=
16123.1
¦ 4 8=
6.49887574
156=
7210 .5
¦ 49=
1.03982010
• 57 =
5098.6
-*50=—
— .25995503
158=
1612.3
*51 =
.064988756E


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SEO NC. 000242	108-
¦ 10
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(06= TEX 		«17
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FCC
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¦ 12= n
¦ 16=
¦	19=
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¦	21 =
¦	23=
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¦	27=
¦ 22=
- (28=	(36=
(29=	137=
¦ 30=	*38=
(31= 	(39=
¦32= 1298.1390 140=
¦	33= 90.0 141 =
g J%=	.03	M2=
¦	35= 7.7403 143=
SEQ NC. 000243	— 108= 32S747N 109= 0964750U «19=	128=	»36=-		»44=	II 77 .3304- (52= - 51114 .9
¦10= FCC	«20=	«29=	(37=	(45= 588.665215 *53= 32327.9
¦01= *04SCJ »S2= R	#11=	*21= *22= *30=	138=	(46= 104.509118 154= 22859.3
¦	03= RHUS		*1I=-S0	«12=-H	«23=	«31=	»39-	»47=	26.127280 - »55= 161£3.9
¦04=	(14=	124=	(32= 1310.3868 *40=	(48= 6.53181988 (56= 7228.7
(05= KS2XEK	*15=	*16=	(25=	*33= 89.8	>41=	(49= 1.04509120 (S7= 5111.5
¦	06= TE*		 #17=		*26=	*34=	.03	*42=	- *50=——.26127280 - *58=- 1616.4
*07= AOCISOfc	*18=	*27=	135= 7.6680 143=	(51= .0653181S98
SEQ NC. 000244 -
...	
¦ 38=-
32S752N
¦09=-0964241U-
*19=
	
-128s	
¦ 36-
	*44 =
	1216.5218
*52=-
51704.1


¦ 10=
FCC

¦ 20 =

*29=
*37=
*45 =
608.260902
*53=
327C0.5
*01= 2069CK *02=
R
¦ 11 =


¦ 21=
822=
*30=
¦ 38=
¦ 46=
106.932394
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23122.8
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¦ 13=
50 	
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¦ 39=
	*47=—
	26.733099
- *55=
16 350.3
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¦ 14=


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¦ 40=
•48 =
6.68327463
*56=
7312.1
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¦ 15=

SI 6=
*25=

¦33= 89.0
*41 =
•45=
1.06932393
*57=
5170.4
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		 .
*17=
	
	
¦ 26=

¦ 34=	.03-
—¦42=	
*50=
—.26733098
- *58=
1635.0
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*18=


¦ 27=

¦35= 7.3484
¦ 4 3=
(51=
.0668327454


SEO NC. 000245

¦ 08=
325752N
*09= 0964241H
¦ 19=
		
-(28=	
¦ 36=
	*44=—
—1233.4694
- *52=
51955.0


¦ 10 =
FCC

¦ 20=

(29=
¦ 37 =
• 45=
616.734718
*53=
32859.2
*01= 2C6SCL *02=
R
¦ 11 =


¦ 21=
¦ 22=
(30 =
¦ 38=
• 46 =
107.973013
*54=
23235.0
*03= M1445

¦ 13=
so 	
— U2= H —
¦ 23=
		
(31=	
¦ 39=
	• 4 7= -
	26.993253
- -*55=
16429.6
• 04=

*14=

•
¦ 24=

¦32= 1392.1900
¦ 40=
• «!¦-
6.74831331
*56 =
7347.6
*05= KS2XEK

¦ 1S=

*16 =
¦ 25=

¦33= 88.6
¦ 41 =
• 49 =
1.07973014
*51 =
51S5.5
*06= IE*
			
*17=-
	
			
¦ 26=
	
¦34= .03
¦ 42=
• 50 =
—.26993253
*58=
1643.0
*07= RIChARCSOft

*18=


¦ 27=

*35= 7.2174
¦ 43=
•51 =
.0674831336


SEO NC. 000246

*08=
335501N
*09= 11 8232SU
*19=

*28=	
- 136=
	*44=—
	70.8834
—*52=-
12406.6


*10=
FCC

¦ 20 =

*29=
¦ 37=
• 45 =
35.441724
*53 =
7846.£
*01= 2CCCSX *02=
R
*11=


¦ 21 =
¦ 22=
*30 =
*38=
*46=
6.156915
*54=
5548.4
*03= nnoi

*13=
2.8
*12= P
¦ 23=

(31 =
*39=	
	IUJ=
- - 1.539229
*55=
3923.3
*04= M2200

*14=


¦ 24=

*32= 80.6276
*40 =
*48 =
.28480717
*56=
1754.6
*05= »C2>U*

¦ 15=

*16 =
¦ 25=

*33= 87.9
*41 =
• 45=
.06156914
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12 40.7
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.. .
¦ 17=
			
-. ... -	
¦ 26=
		
#34= 	.03
~«42=
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— .01539225
lil:
3V2.3
*07= EL SECLN00

*18=


¦ 27=

¦35= 6.9789
¦43=
*51=
.00 384807 IE


3
a
Figure E-4. Sample EPA Master Data Base print - other (960.0 MHz and above).	£
M

-------
EPA
M
n
TABLE OF CONTENTS	O
O
FIELO NO DESCRIPTION OF FIELDS	7
00
1	FRRS RECORD IDENTIFIER - A 6-CHARACTER ALPHANUMERIC CODE THAT UNIQUELY IDENTIFIES EACH FREQUENCY	^
RECORD IN THE CFEF. THE FIRST CHARACTER IDENTIFIES THE SUBFILE TO UrflCH THE RECORD BELONGS (SEE O
CODES BELOW). THE LAST FIVE ALPHANUMERIC CHARACTERS CONTAIN INFORMATION THAT IS SIGNIFICANT TO THE VO
ECAt PR OCRAHMING DEPARTMENT ONLY. w
EXPLANATION OF FIRST DIGIT COOES FOLLOW:
1	- IRAC(GHF)
2	= FCC.
2	RECORD TYPE INDICATOR - DENOTES RECORD CATEGORY
EXPLANATION OF THE CODES FOLLOW:
A : AH BROADCAST
F = FN BROADCAST
I = TELEVISION VIDEO
U = TELEVISION AUDIO
E r EARTH STATION HUN BEAM
S = EARTM STATION OFF-AXIS
C s CIVILIAN FIXED BEAN RADAR
0 = CIVILIAN SCANNING BEAH RADAR
H = HILITART FIXED BEAH RADAR
N = MILITARY SCANNING BEAH RADAR
D - OTHER I 10.KHZ TO 100.KHZ)
P s OTHER ( 100.I KHZ TO 30.561 HHZ)
0 = OTHER I 30.5611 HHZ TO 960. HHZ)
(pi	H = CTHER < GREATER THAN 960. HHZ).
M
3	FREQUENCT - THE OPERATING FREQUENCY OR LOWER LIMIT OF A RANSE OF FREQUENCIES USED BY THE UNIT DESCRIBED
IN THE RECORD. THE BREAKPOINTS FOR THE USE OF A FREQUENCY VALUE PREFIX ARE AS FOLLOWS:
BLANK - 0 TO 29 999 KHZ
H - 30 TO 99999 HHZ.
4	FREQUENCY - UPPER LIMIT OF k RANGE.
5	TRANSMITTER CALL SIGN - A UNIQUE ALPHANUMERIC IDENTIFIER OF A TRANSMITTER (INTERNATIONAL* TACTICALi OR
VOICE). FOR ATCT RECOROS THE OTHER END OF A PARTICULAR LINK IS REFLECTED. HOST CALL SIGNS NO LONGER
HAVE RELIABLE! DIRECTLY DECOOABLE INFORMATION; THE<
-------
TR ANSMI ITER ANTENNA LOCAT ION-FULL - THE BASE* C ITT. OR GEOGRAPHICAL AREA UHCRE THE TRANSMITTER
ANTENNA IS LOCATED. (IB CHAR )
1J	AGENCY - AN ABBREVIATION OF THE AGENCY RESPONSIBLE FOR THE ASSIGNMENT. (6 CHAR!
-	M
8	TRANSMITTER LATITUDE - FOR FIXED COMMENT: THE LATITUDE OF TRANSMITTER ANTENNA* IN DEGREES* MINUTES,	g
AND SEC3NOS (N OR St.	n
- ... - - (
9	TRANSMITTER LONGITUDE - FOR FIXED EQUIPMENT! THE LONGITUOE OF TRANSMITTER ANTENNA, IN DEGREES,	O
HI NUT ES i AND SECONDS tC OR U). J
00
NJ
I
II	TRANSMITTER SYSTEM NOHENCLATURE-~*N~irPH»NUHr*TC-NOMPNCLITURp~DO
SYSTEM HE INC USED.	w
1? ¦— TRANSMITTER FOUER TrPC-Jir-CHlRJl CTER ALPHA CDDE~DENOTIHfTHETYPT OTPDUFR 3UPPLTED TO THE AMTTHK
TRANSMISSION LINE. THE CODE IS OETCRMINEO BT THE EMISSION MODULATION TYPE.
CARRIER IC» - FOR A3 SOUND BROAOCASTING
	HE Ad 
-------
M
Q
>
O
t
22	TRANSMITTER ANTENNA POLARISATION - A CODE OENOTING THE DIRECTION OF THE FIELD RAOIATING FROM	2
~ THE ANTENNA UITH RESPECT TO THE EaRTMS SURFACE. "II CHARI	I
oo
0 - ROTATING
	F - *5 DEGREE	
J - LINEAR
R - RIGHT-HAND CIRCULAR (HELICAL!
- - 	 v - VERTICAL		
X - OTHER
E - ELLIPTICAL
H —"H OR IZONTAU	o
L - LEFT-HAND CIRCULAR (HELICAL!
T - RIGHT/LEFT-HAND CIRCULAR	w
S~- HORIZONTAL t VERTICAL	~
23	TRANSMI TTEfc"AMtCMHA~Ft XCB AMHUTH - TMC A»GLE {JF1hC TRAM SHUM MG'AkTENm^HCASURCir !«DEG*EES	
CLOCKWISE FRCH TRUE NORTH.
2» 1ST SATELLITE ^RANSHITTC*~A7 iHUTHANfitr^- DISS J ETEINTENNA"ANGLrr'l)«T;TRSrTlHirH*IIGE~OFftor*Tl(»tr OF-
A TRACKING TTPE ANTENNA (IV DECREES). A SiCONO OISCRETE AZIMUTH UILL BE REPORTED FOR A 2-SEOS TAT IONART
SATELLITE ST STEM. A RANGE UILL BE REPORTED FDR NON-GEOS, OR MORE THAN TUO 6E0S SATELLITES.
i> 2N0 SATELLI IE TRANSMITTER AZINUTH ANGLE - THE 2 NO SATELLITE TX AZIMUTH Oft RANGE OF ROTATION OF A
TRACKIN5 TTFE ANTENNA (IN DEGREES!.
2S	ANTENNA HORIZONTAL ARC SCANNED FR3H - THE LIMIT (DEGREES, MEASURED CLOCKWISE FRON TRUE NORTH!
FROM UHICH THE ARC IS SCANNEO IN THE HORIZONTAL PLANE BT THE POINT OF MAXIMUM GAIN OF THE ANTENNA
RADIATION PATTERN;
2/ ANTENNA HORIZONTAL ARC SCANNED TO - THE LIMIT (DEGREESt MEASURED CLOCKUISE FROM TRUE NORTH! TO UHICH
THE ARC
GO	PATTERN.
f		THE ARC IS SCANNED IN THE HORIZONTAL PLANi BT THE POINT OF MAX I HUH GAIN UF~THE ANIE NNA R A31 AT ION
28 TRANSMITTER ANTENNA HORIZONTAL NOriON RATE~THE *EVOLUnDI(SrPCR MINUTE IRPIO FOR AMTENNAS MTATTlfG	
THROUGH J40 DEGREES, OR THE SCANS PER PINUTE  FOR ANTENNAS SCANNING AN ARC OF LESS THAN 360
DEGREES. ROT AT IN6 OR SCANNIN6 ACTION HAY BE ACHIEVED BT EITHER MECHANICAL J)R ELECTRICAL HEANS.
2!	TRANSMITTER ANTENNA HORIZONTAL BEAMUIOIH - A * CHARACTER NUMERIC INDICATING THE A1GULAR UIOTH
(DEGREES! BETUEEN THE HALF-POUER POINTS OF TH? MAIN LOBE OF THE ANTENNA HORIZONTAL RADIATION PATTERN.
(THE LOBE CONTAINING THE MAXIMUM ISOTROPIC CAIN.!	
30	TRANSMITTER ANTENNA VERTICAL BEAHU IOTH - THE ANGULAR UIDTH (DEGREES! BETUEEN THE HALF-POUER POINTS OF
THE RAIN LOBE OF THE ANTENNA VERTICAL RADIATDN GAIN PATTERN. (THE LOBE CONTAINING THE MAXIMUM
ISOTROPIC GAIN!.
3	1	TRANSHrTTCR ANTEMNA TLrVATrOfTANfiLir^-'THr TILT^AHGLE Or THr PAOIATINC BEAH HEJISURrD lN OEG&EES ABOVE
(*! OR BELOU (-1 THE HORIZON.
32	— ON-AX IS POUER 0ENSITT"IHU/CM2I~ AT THE ' NEAT FIELO OISTANCE
33		NEAR-FIELO ^BOUNDARY DISTANCE (METERS! OERI/EO FROM FREQUENCY AND GAIN
3*	WAVELENGTH (RETERS! OERIVEO FROM FREOUENCY	tg"
T3
J5 ANTENNA ARC A (METER SI SQUARED DDE A IVEDFRDR~GAIN	18
3
a.
Figure E-5. (Page 3 of 4) .	h-
M

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M
n
>
0
1
n
*}
i
oo
"37	ROTATION-KCDUCTIONAL FALTOR (UNIIirSSrurJiniETER5		I
o
3	8	ROTATION RE0UCT10NAL FACTOR IUNITLESSI AT 500 MEIERS 		£
39	ROTATION RE DUCTIONAL FACTOR IUNITLESSI AT I KILOMETER
3&	ROTATION RCOUCT IONAL FACTOR IUNITLESSI AT 100 NETERS
4	0	ROTATTUR'UFDUCTTONAE FACTOR tUNITLCSSl _AT 2~KTL OHETERS
41	ROTATION REOUCT IONAL FACTOR IUNITLESSI AT S KILOMETERS
42	ROTATION REOUCIIONAL FACTOR IUNITLESSI AT 10 KILOMETERS
4	3	ROTAnOirmmUCnONACTIlCTOR nJNITL~ESSr~AI ZITTtTLONETERS-
44	POWER OENSITT IHU/CH2I AT 100 METERS
45	POWER OENSITV IMW/CW2I	AT 200 METERS
«S	PDUCRTMSITI-! MU/CMZJ	*r~50B~METERS
M
I	4? 	POWER OENSTTT IMW/CM2I	AT 1 KILOMETER
\
M
i
49 POWER OENSI T* I MW/CM2I AT 2 KILOMETERS
4«	POWER ~DCllSITY_rWI/CT21 JirTT-KILOMETERS-
50	POWER OENSITT IMW/CM21 AT 10 KILOMETERS	
St	POWER OENSIT1 IMW/CM2I AT 20 KILOMETERS
52 ~	DISTANCE I METER SI* TOR~POWCR DENSITY' 0« 01 MW /CH2
5)	DI STANCE I METERS! FOR POWER DENSITY 0.025 MW/CM2
54	OISTANCE (MEIERS! FOR POWER OENSITY 0.05 NW/CM2
5	5	DISTANCE-! METERS! ~TOR-pOWEIT_DENSITY~ o;;rMII/TII2	
5u 	OISTANCE^IMETERSI FOR POUER^ DENSITY 0.5^
5T DISTANCE IMEIERSI FOR POWER DENSITY 1.0 MW/CM2
58	OTSTANCE'TMETtHSl FOR^PqUER DENSITY 10.0 RW7CNJ-
Figure E-5. (Page 4 of 4).
5
•o
(i)
p
Oj
H-
X
PI

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DISTRIBUTION LIST FOR
SUPPORT TO THE ENVIRONMENTAL PROTECTION AGENCY NONIONIZING
RADIATION SOURCE ANALYSIS
ECAC-CR-82-093
Addressee	No of Copies
The U.S. Environmental Protection Agency	10
Attn: Mr. N. Hankin, ANR 461
Crystal Mall II
401 M Street SW
Washington, DC 20460
The U.S. Environmental Protection Agency	10
Attn: Mr. R. Tell
P.O. Box 18416
Las Vegas, NV 89114
HQ USAF/FMC	1
Washington, DC 20330
Chief of Naval Operations (0P-941F)	1
Navy Department
Washington, DC 20350
Director	1
Naval Electromagnetic Spectrum Center
4401 Massachusetts Avenue, NW
Washington, DC 20390
Commander (ELEX-832A)	1
Naval Electronic Systems Command
Washington, DC 20360
Internal
CJ/P. Mager	1
DFA/V. Nanda	1
DIO/F. Tushoph	3
DIO/S. Ream	1
DRS/B. Watson	1
DRS/D. Williamson	1
DQP/K. Woodcock	1
DIL	10
DIL Camera-Ready

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fuMu 1/ i / P tc lio
Appendix, ECAC-CR-82-093
;•:>¦>• i'v jt Lnvironmental
POWER DENSITY/DISTANCE HISTOGRAMS	, unecuen Agency Library MS-541
As part of em interagency agreement, (IAG-AD-21-F-2-802-0), betWW lo&1986
United States Environmental Protection Agency and the Electromagnetic
Compatibility Analysis Center, three types of power density,
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The 15 categories of emitters are:
1.	AM broadcast stations (535-1605 kHz)
2.	FTO broadcast stations (88-108 MHz)
3.	TV broadcast stations (54-88, 174-216, 470-890 MHz)
4.	Composite of all broadcast stations
5.	Civilian fixed beam radar stations (off-axis antenna gain only)
6.	Civilian scanning radar stations (off-axis antenna gain only)
7.	Military fixed beam radar stations (off-axis antenna gain only)
8.	Military scanning radar stations (off-axis antenna gain only)
9.	Satellite earth stations (mainbeam antenna gain)
10.	Satellite earth stations (off-axis antenna gain)
11.	Other stations (10-100 kHz)
12.	Other stations (100.1 kHz-30.56 MHz)
13.	Other stations (30.56-960.0 MHz)
14.	Other stations (960.0 MHz and above)
15.	Composite of all stations (except satellite earth stations
antenna mainbeam)
The histograms are numbered by the type and category of emitter, thus the
type A histogram for AM broadcast stations, which produce a minimum power
density of 0.025 mW/cm , is numbered A1-1. Histograms are not provided for
those combinations of type and category for which there are no qualifying
systems.
Further information on the histograms, their data sources and the
metholodogies used in their creation, is to be found in ECAC CR-82-093.
2

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type a histograms
3

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AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=G6i8
TOTAL NUMBER PR0CESSED=6618
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
DISTANCE IN METERS
Figure Al-1. Number of assignments for AM broadcast2stations which can produce
a minimum power density of 0.025 mW/cm .

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300 T
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=66i8
TOTAL NUMBER PROCESSED=GG10
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
N
U
M
0
E
R
0
F
200 ¦¦
A
S
S
I
G
M 100
§
I
0
3*
230
I
0%
0*
0%
0%
0X
0%

0
0
0
0
0
0
0-
200
500
IK
2K
5K
I0K
20K
DISTANCE IN METERS
Figure Al-2. Number of assignments for AM broadcast stations which can produce a minimum
power density of 0.05 mW/crn^.

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AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=66iB
TOTAL NUMBER PROCESSED=B610
POWER DENSITY GREATER THAN OR EQUAL TO .1 MV/CM2
300
N
U
M
B
E
R
0
F
A
S
S
1
G
N
T
S
200 -
100 -
0
035
0X
0X
0X
0X
0%
0X
0
0
0
0
0
0
0.
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure Al-3. Number of assignments for AM broadcast stations which can produce a minimum
power density of 0.1 mW/cm2.

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4000
N
U
M 3000
2000 • •
1000
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=902i
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
0
0*
0%
0*
0%
0SK
0*
0*
18
0
0
0
0
0
0.
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure A2-1. Number of assignments for FM broadcast stations which can produce a
minimum power density of 0.025 mW/cm^.

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00
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
2000 t
1000 -
20*
1046
I
0%
9
0*
0
0X
0
-t-
1K

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FM BROADCAST
TOTAL NUMBER OF A5SIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
DISTANCE IN METERS
Figure A2-3. Number of assignments for FM broadcast station which can produce
a minimum power density of 0.1 vM/ctsfi-.

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T\/ RPDAnrACT
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSEDM037
POWER OENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
DISTANCE IN METERS
Figure A3-1- Number of assignments for TV broadcast stations which can produce
a minimum power density of 0.025 mW/cm2.

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TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTSM037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
DISTANCE IN METERS
Figure A3-2. Number of assignments for TV broadcast stations which can produce
a minimum power density of 0.05 mW/cm2.

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TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
N
U
M
B
E
R
0
F
A
S
900 T
600 t
700 +
600 |
500
400 }
G
fj 300
5
I 200
100 +
0
100 200
18
54
500
0%
0X
0X
0X
0X
0
0
0
0
0
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure A3-3. Number of assignments for TV broadcast stations which can produce
a minimum power density of 0.1 mW/cm^.

-------
43a
T\/ RPftAnTACiT
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
N
U
M 300
B
E
R
0
F
A 200 +
5
s
r
G
N
M
E
N 100
S
0
2%
04
1
0*
X
Q%
0
0%
0
0%
0
0*
0
0%
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure A3-4. Number of assignments for TV broadcast stations which can produce a
minimum power density of 0.5 mW/cm^.

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TV BDninrACT
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
300
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
200 -
100
0
0*
0
	~—
100 200
0%
0
—i—
500
0*
0
IK
Z%
0
2K
0%
0
—i—
5K
0%
0
—t—
10K
0%
0
*
20K
DISTANCE IN METERS
Figure A3-5. Number of assignments for TV broadcast stations which can produce a
minimum power density of 1.0 mW/cm2.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS®19B7G
TOTAL NUMBER PR0CESSED=19676
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
5000
N 4000
M
B
E
R
0 3000
F
A
S
S
J 2000 -
N
M
S 1000 - -
0
2%
333
r
0%
54
100 200
500 IK
DISTANCE IN METERS
0X
?
0*
0X
0
0*
0.
2K
5K
10K
20K
Figure A4-1. Number of assignments for broadcast stations which can produce a
minimum power density of 0.025 mW/cm^.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PROCESSED-19676
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
4000
N
M 3000
B
E
R
0
F
& 2000
N
i
1000 -
0
16*
3161
I
KO 762
Jj
100 200
IS
174
m
0*
0
0%
Jr-
0%
0
500 IK 2K 5K
DISTANCE IN METERS
0X
0
10K
055
0.
20K
Figure A4-2. Number of assignments for broadcast stations which can produce a
minimum power density of 0.05 mW/cm2.

-------
2000
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PROCESSED=19676
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
g
I
1000 -
0
5*
1071

0%
54
P?7I
100 200
500
0%
0%
0*
0X
0*
?
0

0
0
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure A4-3. Number of assignments for broadcast stations which can produce a minimum
power density of 0.1 mW/cm^.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=i9S76
TOTAL NUMBER PR0CESSED-19G7G
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
2%
DISTANCE IN METERS
	
Figure A4-4. Number of assignments for broadcast statioris2which can
produce a minimum power density of 0.5 mW/cm .

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=JL9676
TOTAL NUMBER PROCESSED-19676
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
300
N
U
M
B
E
R
0
F
Si
200 ¦
A
S
S
I
G
H 100
0
1%
223
100
0X
0
200
0*
0
1
500
0%
0
—i—
IK
0K
0
¦¦ i
2K
0*
JL
5K
e%
0
—I—
10K
0*
-3L
20K
DISTANCE IN METERS
Figure A4-5. Number of assignments for broadcast stations2which can
produce a minimum power density of 1.0 mW/cm .

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY GREATER THAN OR EQUAL TO .025 MV/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
70
80
50 ¦¦
40
30
20 --
10
0
14*
66
10%
48

*2
5%
22
4%
21
J
0X
0

0X
0
0*
0
0X
-2=-
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure A5-1. Number of assignments for civilian fixed beam radar stations ^
which can produce a minimum off-axis power density of 0.025 mW/cm .

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
60 r
50 •
4.0 ..
30
20 -
10 ¦
0
12*
57
10%
45
I
4*
21
s
056
0
0%
0
0%
0
0%
0
0X
0
100 200
-4-
500 IK	2K	5K
DISTANCE IN METERS
-H
10K 20K
Figure A5-2. Number of assignments for civilian fixed beam radar stations which can
produce a minimum off-axis power density of 0.05 mW/cm2.

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
DISTANCE IN METERS
	—	_____	1
Figure A5-3. Number of assignments for civilian fixed beam radar stations
which can produce a minimum off-axis power density of 0.1 mW/cm .

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CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=839
TOTAL NUMBER PR0CESSED=472
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
DISTANCE IM METERS
Figure A5-4. Number of assignments for civilian fixed beam radar stations
which can produce a minimum off-axis power density of 0.5 mW/cm .

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CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PROCESSEDM72
POWER DENSITY GREATER THAN OR EQUAL TO i.0 MW/CM2
DISTANCE IN METERS
Figure A5-5. Number of assignments for civilian fixed beam radar stations ^
which can produce a minimum off-axis power density of 1.0 mW/cm .

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CIVILIAN SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=594
TOTAL NUMBER PR0CESSED=593
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
2 T
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
1 -
0
0*
0*
0X
0%
0*
0%
08
0
0
0
0
0
0
0.
2Z€
500
IK
2K
5K
10K
20K
100
DISTANCE IN METERS
Figure A6-1. Number of assignments for civilian scanning radar stations	2
which can produce a minimum off-axis power density of 0.025 mW/cm .

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MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS-307
TOTAL NUMBER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
DISTANCE IN METERS
Figure A7-1. Number of assignments for military fixed beam radar stations
which can produce a minimum off-axis power density of 0.025 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUI-BER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
i
s
50 T
40 -
30 ••
20
10 ¦
0
15*
44
I
3%
28
1
1 I
I.
7%
20
i

458
12	3%
U
IX
2
YZZL
¥
100 200 500 IK	2K	5K
DISTANCE IN METERS
IX
m
0%
0.
10K
20K
Figure A7-2. Number of assignments for military fixed beam radar stations which
can produce a minimum off-axis power density of 0.05 mW/cm^.

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
DISTANCE IN METERS
Figure A7-3. Number of assignments for military fixed beam radar stations
which can produce a minimum off-axis power density of 0.1 mW/cm .

-------
20 T
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF AS5IGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
N
U
M
B
E
R
0
F
A
S
5
1
G
N
M
E
N
T
S
10
0
5*
14
I
3*
e
i%

IK
2
IX
2
500	IK	2K	5K
DISTANCE IN METERS
0%
0
¦ t
10K
0%
0
—K-
20K
100 200
Figure A7-4. Number of assignments for military fixed beam radar stations which can
produce a minimum off-axis power density of 0.5 mW/cm^.

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
20
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
5
10 •
0
4%-
13
I
100
3%
9
!
200
3%
I'-
111
500	IK	2K	5K
DISTANCE IN METERS
IX
2
7?
0%
0
—i—
0*
0
—i—
10K
0X
0
20K
Figure A7-5. Number of assignments for military fixed beam radar stations ^
which can produce a minimum off-axis power density of 1.0 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
0 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
7
B ¦¦
5 -
4 ••
3 ¦¦
2 ¦¦
1 ¦
0
2%
100
IX
2
I
200
1*
2
I 1
I
0%
a
m
0
0X
0
500 IK	2K	5K
DISTANCE IN METERS
0%
0
—i—
10K
0*
0 -
—t—
20K
Figure A7-6. Number of assignments for military fixed beam radar stations
which can produce a minimum off-axis power density of 10.0 mW/cm^.

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF A5SIGNMENTS=i050
TOTAL NUMBER PROCESSED=1049
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
N
U
M
B
E
R
0
F
I
G
N
M
§
s
50 T
40
30
20 -
10 ¦¦
0
3*
40
I
2%
36

0*
0	0%
Li
0*
0
0X
0
-t-
0*
2
-h
10K
0*
0
20K
100 200
500 IK	2K 5K
DISTANCE IN METERS
Figure A8-1. Number of assignments for military scanning radar stations which can
produce a minimum off-axis power density of 0.025 mW/cm2.

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1056
TOTAL NUMBER PR0CESSED=1849
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
DISTANCE IN METERS
Figure A8-2. Number of assignments for military scanning radar stations	2
which can produce a minimum off-axis power density of 0.05 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1B58
TOTAL NUMBER PROCESSED=1049
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
DISTANCE IN METERS
Figure A8-3. Number of assignments for military scanning radar stations
which can produce a minimum off-axis power density of 0.1 mW/cm .

-------
20
MILITARY SCANNING RADAR
TOTAL NUMBER OF AS5IGNMENTS=105B
TOTAL NUMBER PROCES5ED=1049
POWER DENSITY GREATER THAN OR EQUAL TO .5 MV/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
10
0
e%
s
0%
0X
0*
0%
0*
0%
0
0
0
0
0
0
500
IK
2K
5K
10K
20K
100
200
DISTANCE IN METERS
Figure A8-4. Number of assignments for military scanning radar stations ^
which can produce a minimum off-axis power density of 0.5 mW/cm .

-------
0 T
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1050
TOTAL NUMBER PR0CESSED=1649
POWER DENSITY GREATER THAN OR EQUAL TO JL0 MW/CM2
N
U
M
B
E
R
0
F
I
G
N
M
E
I
7
6
5 •
4- •
3
2
1
0
0*
1
02
0
0%
0
0%
0
0*
0
0X
0
0X
0
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure A8-5. Number of assignments for military scanning radar stations ^
which can produce a minimum off-axis power density of 1.0 mW/cm .

-------
EARTH STATIONS CMAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
1200
1100 •
N
U 1000
M
B
E
R
76*
1146
0
F
A
S
S
1
G
N
M
E
N
T
S
900
800
700
600
500
400 ••
300

71*
1073

100 200
64*
969

61%
914
I

57*
056
i
50*
754
i
500 IK
DISTANCE
35*
531
1
31*
475
i
2K	5K
IN METERS
10K
20K
Figure A9-1. Number of assignments for earth stations which can
produce a minimum mainbeam power density of 0.025 mW/cm .

-------
EARTH STATIONS CMAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED®1509
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
1100 T
1000
900 -
600
700
600
500 ¦¦
400
300 -
200
72*
1001

67*
1012

61%
915 58%
872


100 200 500 IK
DISTANCE
50%
758
i
47*
711
I
32*
479
i
26*
393
1
2K	5K
IN METERS
10K
20K
Figure A9-2. Number of assignments for earth stations which^can produce
a minimum mainbeam power density of 0.05 mW/cm .

-------
EARTH STATIONS CMAIN8EAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
1000
900 -
600
700
600 +
500
400
300
200
100
62%
931
1

56*
042
1
1 i


51%
772
I
47*
714
I
(A
100 200 500 IK
DISTANCE
4255
639
!
29%
427

20%
410
I
I
19%
291
2K	5K
IN METERS
10K
20K
Figure A9-3. Number of assignments for earth stations which
can produce a minimum mainbeam power density of 0.1 mW/cm .

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
700 r
600 -
N
U
M
B 500
R
0
F <00
A
S
G
N
M
E
N
T
S
300 -
200 -
100 ¦
0
41*
G13
I
37*
560
I
33*
503
I
29*
431
i
15*
221
1
14*
217
I
5*
77
I
2*
33
m.
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure A9-4. Number of assignments for earth stations which can
produce a minimum mainbeam power density of 0.5 mW/cm .

-------
EARTH STATIONS CMAIN8EAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
500 T
N 400
M
B
E
R
0
F
A
S
S
1
G
N
M
I
I
300
200 -
100 ••
0
30*
454
I
23%
434

22%
333
i
20%
309
i
7%
113
I
6X
65
¦
2%
35
2*
25
m VA
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure A9-5. Number of assignments for earth stations which can
produce a minimum mainbeam power density of 1.0 mW/cm .

-------
EARTH STATIONS CMAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
N
U
M
B
E
R
0
F
300
200 --
I
G
H 100
i
i
0
19*
293
151
226

1%
19
IX
IS
IX
16
IX
15
S3	f^l	E2-
<¥¦
500 IK	2K	5K
DISTANCE IN METERS
IX
12
IX
11
YZ&.
100 200
10K
20K
Figure A9-6. Number of assignments for earth stations which can
produce a minimum mainbeam power density of 10.0 mW/cm .

-------
EARTH STATIONS COFF-AXISD
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
500 t
400
300 ¦¦
200 -
100 ••
0
29%
433
I

24%
365
¦
1

5%
73
¦
2%
33
2%
26
IX
12
_Z$Z_
100 200
500	IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure AlO-1. Number of assignments for earth stations which
can produce a minimum off-axis power density of 0.025 mW/cm .

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
400 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
300 -
200 --
100 -
0
25%
383
I
10*
26B
I
16%
248
i
4%
53
¦
1%
21
m
i%
15
Y7A
i«
14
i%
n
_E3ZL
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure AlO-2. Number of assignments for earth stations which can 2
produce a minimum off-axis power density of 0.05 mW/cm .

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=i509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
20*
DISTANCE IN METERS
Figure AlO-3. Number of assignments for earth stations Which can ^
produce a minimum off-axis power density of 0.1 mW/cm .

-------
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
Figure AlO-4. Number of assignments for earth stations which can
produce a minimum off-axis power density of 0.5 mW/cm .

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
13 T
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
12 ¦¦
11 ••
10
9 •
8 ••
IX
12
I

IX
12

IX IX
12	12
7771 V,
1


IX
11
1
I
IX
9
1
<2
IX
9
1
IX
6
1

-------
00
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
11
10 ¦
9 •
0
IX
10

IX
10

IX
IX IX
"

1

IX

IX
a
i
IX
e
1
100 200
500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure A10-6. Number of assignments for earth stations which^can produce
a minimum off-axis power density of 10.0 mW/cm .

-------
200
OTHER STATIONS C10 KHZ TO 100 KHZJ
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
N
U
M
B
E
R
0
F
A
5
s
1
G
N
M
6
s
100 -
0
07*
152
!
47%
01
3358
59
I
10%
17
M
0%
0
0*
0
0%
0
—i—
10K
0K
0
100 200
500 IK	2K	5K
DISTANCE IN METERS
20K
Figure All-1. Number of assignments for other stations (10kHz to 100kHz)
which can produce a minimum power density of 0.025 mW/cm^.

-------
OTHER STATIONS C10 KHZ TO 100 KHZ3
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PROCESSED-174
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
DISTANCE IN METERS
Figure All-2. Number of assignments for other stations	2
(10kHz to 100kHz) which can produce a minimum power density of 0.05 mW/cm .

-------
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
DISTANCE IN METERS
Figure All-3. Number of assignments for other stations (10kHz to 100kHz) which
can produce a minimum power density of 0.1 mW/cm^.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=1090B
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
7000 T
6000
N
U
fl
B 5000
R
?
A
S
S
I
G
N
M
E
N
T
S
4000 - ¦
3000 --
2000 -
1000 -
0
62X
G791

16*
1722

100 200
3X
372 IX
123
tsf*

0X
23
0X
1
500 IK	2K	5K
DISTANCE IN METERS
0X
0
-t-
0%
JU
10K
20K
Figure A12-1. Number of assignments for other stations (100 kHz £o 30561 kHz) which
can produce a minimum power density of 0.025 mW/cm .

-------
OTHER STATIONS C100 KHZ TO 30561 KHZD
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED-10900
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
3000
N
U
M
B
E
R
0
F
2000 -
A
S
S
I
G
K 1000
E
N
T
S
0
23%
2531

7%
703
I
100 200
IX
140
XT
m
IX
91
'A	VTA
0X
10
0X
1
-H
500	IK	2K	5K
DISTANCE IN METERS
0X
0
1
10K
0X
4*
20K
Figure A12-2. Number of assignments for other stations (100 kHz to 30561 kHz)
which can produce a minimum power density of 0.05 mW/cm2.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=10908
TOTAL NUMBER PROCESSED=10900
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
2000
N
U
M
B
E
R
0
F
A
S
S
1
N
M
E
N
T
S
1000 ¦
0
15%
16 70

4%
496
I
100 200
IX
117 z%
23
0X
1
0X
0
0%
0
—H—
0%
JU
500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure A12-3. Number of assignments for other stations (100 kHz to 30561 kHz) which
can produce a minimum power density of 0.1 mW/cm^.

-------
OTHER STATIONS (100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED310908
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
500
N 400 ..
M
B
E
R
0 300
F
A
S
S
I
G
N
M
IS
s
200 -
100 --
0
0X
20
m.
058
1
0*
0
—~—
0%
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
0X
0
—i—
10K
0%
0
> ¦
20K
Figure A12-4. Number of assignments for other stations (100 kHz to 30561 kHz) which
can produce a minimum power density of 0.5 mW/cm2.

-------
OTHER STATIONS C100 KHZ TO 30581 KHJD
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2

90 -

80 ¦
N

U
70 ¦
M

5

E
R
60 -
0

F
50
A

S

S
40 -
I

G

N
M
30 •
E

N

T
S
20

10 ••

0 ¦
0*
1
0%
1
0*
0
0*
0
056
0
0*
0
—i-*-
100 200
500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure A12-5. Number of assignments for other stations (100 kHz to 30561 kHz) which
can produce a minimum power density of 1.0 mW/cm^.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10908
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
5
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
4 ••
3 -
2 ¦¦
1 ¦
0
0*
0
0%
0
0*
0
—i—
2K
100 200 500 IK
DISTANCE IN METERS
Z%
0
—i—
5K
0%
0
1
10K
0X
0
20K
Figure A12-6. Number of assignments for other stations (100 kHz to 30561 kHz) which
can produce a minimum power density of 10.0 mW/cm2.

-------
OTHER STATIONS C30.5B1 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
POWER DENSITY GREATER THAN OR EQUAL TO .025 MV/CM2
N
U
M
B
E
R
0
F
A
5
s
1
G
N
M
6
I
100 T
90
00
70
60
50
40
30
20
10
0
768!
96

22%
28
1
ex
10
ex
10

2%
3
JZZZL
2%
2
17771
0X
100 200
500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure A13-1. Number of assignments for other stations (30.561 MHz to 960 MHz) which
can produce a minimum power density of 0.025 mW/cm2.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=i27
TOTAL NUMBER PR0CESSED=127
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
DISTANCE IN METERS
Figure A13-2. Number of assignments for other stations (30.561 MHz to 960 MHz) which
can produce a minimum power density of 0.05 mW/cm2.

-------

-------
40 r
OTHER STATIONS O0.5G1 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
I
S
30
20 -
10
2
0%
10
I
2%
3
2%
2
H	m
0X
0
0*
0
0%
0.
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
-t-
20K
Figure A13-4. Number of assignments for other stations (30.561 MHz to 960 MHz) which
can produce a minimum power density of 0.5 mW/cm2.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=i27
TOTAL NUMBER PROCESSED-127
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
DISTANCE IN METERS
Figure A13-5. Number of assignments for other stations (30.561 MHz to 960 MHz) which
can produce a minimum power density of 1.0 mW/cm2.

-------
OTHER STATIONS C30.5Gi MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED=127
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
5 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
g
s
4
3
2
1
0
3%
4
100
2%
I
200
2%
1
0*
0
0X
S-
0*
0
50r IK	2K	5K
DISTANCE IN METERS
0X
0
1
10K
0X
0.
20K
Figure A13-6. Number of assignments for other stations (30.561 MHz to 960 MHz) which
can produce a minimum power density of 10.0 mW/cm^.

-------
OTHER STATIONS C960 MHZ AND ABOVE!
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PR0CESSE0-299
POWER DENSITY GREATER THAN OR EQUAL TO .025 MV/CM2
300
N
U
M
B
R 200
0
F
I
C
" 100
5
S
0
96*
207
50*
149
I
43%
147
S
J
47* 4658
141 139 43*
129


14SB
42
ex
25
I_1
100 200
500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure A14-1. Number of assignments for other stations (960 MHz and above) which
can produce a minimum power density of 0.025 mW/cm2.

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
200 T
N
U
M
B
E
R
0
F
A
S
S
1
G
M
M
i
I
100 ¦¦
0
66X
198
49X
147
*7t
143 141
i

SI
46X
137
I
23%
70
I
9X
27
1
ex
23
1
100 200
500 IK
DISTANCE
2K	5K
IN METERS
10K
20K
Figure A14-2. Number of assignments for other stations (960 MHz and above) which
can produce a minimum power density of 0.05 mW/cm2.

-------
en

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSED=299
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
200
Figure A14-4. Number of assignments for other stations (960 MHz and above) which
can produce a minimum power density of 0.5 mW/cm2.

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PROCESSED-299
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MW/CM2
DISTANCE IN METERS
Figure A14-5. Number of assignments for other stations (960 MHz and above) which
can produce a minimum power density of 1.0 mW/cm2.

-------
200
OTHER STATIONS C9B0 MHZ AND ABOVE)
TOTAL NUMBER OF" ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
I
100
0
461
137
ex
25
BX
6X

19
ie
i

i


2%
5
7J?I
IX
3
JCZ^L
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure A14-6. Number of assignments for other stations <960 MHz and above) which can
produce a minimum power density of 10.0 mW/cm2.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS»36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY GREATER THAN OR EQUAL TO .025 MW/CM2
20000 T
N
U
M
B
E
R
0
F
A 10000 -
I
G
N
T
S
0
3535
1254-5

4X
1282 IX
474
	EjZL
IX
256
0X
169
100 200 500 IK 2K 5K
DISTANCE IN METERS
0X
72
¦ i
0X
3L
10K
20K
Figure A15-1. Number of assignments for stations which can
produce a minimum power density of 0.025 mW/cm .

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAMD
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY GREATER THAN OR EQUAL TO .05 MW/CM2
7000 t
6000 -
N
U
M
B 5000
R
F 4000
A
S
S
I
G
N
M
S
3000 -
2000 -
1000 -
0
IB*
6560
I
2%
703
i
100 200
IX
307
IX
182
F^71
0*
90
500 IK 2K
DISTANCE IN METERS
ex
43
0*
34
5K
10K
20K
Figure A15-2. Number of assignments for stations which can
produce a minimum power density of 0.05 mW/cm .

-------
4000 T
N
M 3000
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY GREATER THAN OR EQUAL TO .1 MW/CM2
9
A 2000
?
M
| 1000
S
0
435
1403

IX
302 1%
199
1
0X
154
Y7fl
0X
61
\t f A
0X
39
100 200 500 IK 2K 5K
DISTANCE IN METERS
10K
0*
20K
Figure A15-3. Number of assignments for stations which ca^
produce a minimum power density of 0.1 mW/cm .

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY GREATER THAN OR EQUAL TO .5 MW/CM2
2000 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
1000 -
0
335
1057

IX
302
IX
190
100 200
1
1 n i
0%
151
0*
5B
777I
0X
35
JZ72L
0*
28
0X
27
500 IK	2K	5K
OISTANCE IN METERS
1BK
20K
Figure A15-4. Number of assignments for stations which can^
produce a minimum power density of 0.5 mW/cm .

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS-36291
TOTAL NUMBER PROCESSED»35907
POWER DENSITY GREATER THAN OR EQUAL TO 1.0 MV/CM2
G00 T
500 -
N
U
M
B
| 400
0
F
A 300 ¦
N
N
T
S
200 •
100 -
0
IX
519

IX
249

0X
159
i
0X
95
0X
42

0*
32
m
0X
27
0X
26
m.
100 200 500 IK 2K 5K
DISTANCE IN METERS
10K
20K
Figure A15-5. Number of assignments for stations which
can produce a minimum power density of 1.0 mW/cm .

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCE5SED-35907
POWER DENSITY GREATER THAN OR EQUAL TO 10. MW/CM2
200 r
N
U
M
B
E
R
0
F
A 100
S
1
G
N
M
6
i
0
Z%
1B2
0*
145
I
0Z
55

0%
35
0%
29
0*
27
11"
0*
13
0*
11
100 200
500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure A15-6. Number of assignments for stations which can
produce a minimum power density of 10.0 mW/cm .

-------
TYPE B HISTOGRAMS
76

-------
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=6610
TOTAL NUMBER PROCESSED=6G10
POWER DENSITY RANGE C0.0-.025) MW/CM2
6700 T
6600 +
N
U
M
B 6500
F 6400
A
S
S
I
G
N
6300 4-
6200 +
6100 4-
6000
97*
6401

100* 100$
6610 6610

£77
100* 100% 100%
6610 6616 6610
100 200 500 IK
DISTANCE



100ft
6616
I
I
2K	5K
IN METERS
10K
20K
Figure Bl-1. Number of assignments for AM broadcast stations which can produce power
densities between 0.0 and 0.025 mW/cm2.

-------
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=6610
TOTAL NUMBER PR0CESSED=G61B
POWER DENSITY RANGE C.025-05) MW/CM2
300 r
N
U
M
B
E
R
0
F
200 -
A
S
s
I
G
H 100
E
N
T
S
0
3%
224
|
I
100
3%
217
I
200
0*
0
0%
0
0%
0
500 IK	2K
DISTANCE IN METERS
0X
0
¦ t
5K
0%
0
10K
0X
e.
20K
Figure Bl-2. Number of assignments for AM broadcast stations which can produce power
densities between 0.025 and 0.05.mW/cm2.

-------
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=6610
TOTAL NUMBER PR0CESSED=6618
POWER DENSITY RANGE C.05-.1D MW/CM2
DISTANCE IN METERS
Figure Bl-3. Number of assignments for AM broadcast stations which can produce power
densities between 0.05 and 0.1 mW/cm2.

-------
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=GB10
TOTAL NUMBER PROCESSED=G610
POWER DENSITY RANGE C.1-.53 MW/CM2
300 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
200 ¦¦
100 ¦¦
0
0*
0
1
100 200
0X
0
¦ t
0%
0
—i
0*
0
—t—
0X
0
500 IK 2K	5K
DISTANCE IN METERS
0*
0
—t—
10K
0*
0-
—
20K
Figure Bl-4. Number of assignments for AM broadcast stations which can produce power
densities between 0.1 and 0.5 mW/em2.

-------
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=902i
POWER DENSITY RANGE C0.0-.025) MW/CM2
10000
N
U
M
B
E
R
0
F
A
S
5
1
G
N
M
6
I
9000
6000 -
7000 -
6000 -
5000 ' ¦
99% 100% 100*
9003 9021 9021
4000
67%
5999
s



100% 100%
9021 9021
100 200 500 IK
DISTANCE


100%
9021

100%
9021
I
2K	5K
IN METERS
10K
20K
Figure B2-1. Number of assignments for FM broadcast stations which can produce power
densities between 0.0 and 0.025 mW/cm^.

-------
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
POWER DENSITY RANGE C.025-.055 MW/CM2
DISTANCE IN METERS
Figure B2-2. Number of assignments for FM broadcast stations which can produce power
densities between 0.025 and 0.05 mW/cm^.

-------
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
POWER DENSITY RANGE C.05-.1) MW/CM2
DISTANCE IN METERS
Figure B2-3. Number of assignments for FM broadcast stations which can produce power
densities between 0.05 and 0.1 mW/cm2.

-------
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS-9021
TOTAL NUMBER PROCESSED=9021
POWER DENSITY RANGE C.1-.5D HW/CM2
DISTANCE IN METERS
Figure B2-4. Number of assignments for FM broadcast stations which can produce power
densities between 0.1 and 0.5 mW/cm^.

-------
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED-4037
POWER DENSITY RANGE C0.0-.025) MW/CM2
5000
N
M 4000
B
E
R
0
F
A
S
5
1
G
N
M
6
I
3000 --
1000
72%
2900
2000

73*
3201
92*
3704
100 200

33%
3303

100* 100*
4037 4037

100* 100*
4037 4037

500 IK
DISTANCE


2K	5K
IN METERS

10K 20K
Figure B3-1. Number of assignments for TV broadcast stations which can produce power
densities between 0.0 and 0.025 mW/cm2.

-------
CO
tn
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY RANGE C.025-.053 MW/CM2
200 T
100 ¦¦
0
IX
52
I
2%
62

4*
159
I
1

IX
54

0*
0
0%
0
0%
0
0X
0.
100 200
500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B3-2. Number of assignments for TV broadcast stations which can produce power
densities between 0.025 and 0.05 mW/cm2.

-------
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY RANGE C.05-.15 MW/CM2
400
N
U
m
B
E
R
0
F
A
S
G
N
fi
i
300
200 -
100 "
0
6%
249

6%
326
I
3%
120
1
Z%
0
0%
0
0X
0

z%
0
0.
100
200
500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure B3-3. Number of assignments for TV broadcast stations which can produce power
densities between 0.05 and 0.1 mW/cm2.

-------
tv RBnAnrAQT
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY RANGE C.1-.5) MW/CM2
500 T
[j 400
M
B
E
R
0 300
F
A
S
S
I
G
N
M
E
N
T
S
200
100 ¦¦
0
11*
443

9%
344

IX
54
i
0ft
0
0%
0
0ft
0

0ft
2
10K
0ft
0.
100 200
500 IK	2K	5K
DISTANCE IN METERS
20K
Figure B3—4. Number of assignments for TV broadcast stations which can produce power
densities between 0.1 and 0.5 mW/cm2.

-------
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY RANGE C.5-1.0) MW/CM2
DISTANCE IN METERS
Figure B3-
5.
Number of assignments for TV broadcast stations which can produce power
densities between 0.5 and 1.0 mW/cm^.

-------
0
F
300 T
TV RPOAnPA^T
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
POWER DENSITY RANGE Cl.0-10.0) MW/CM2
N
U
M
B
E
R
200
A
S
S
I
G
N
M
E
N
T
S
100 ••
0
0%
0%
0%
0%
Z%
0*
035
0
0
0
0
0
0
0
200
500
IK
2K
5K
10K
20K
100
DISTANCE IN METERS
Figure B3-6. Number of assignments for TV broadcast stations which can produce power
densities between 1.0 and 10.0 mW/cm2.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=1967S
TOTAL NUMBER PROCESSED-19676
POWER DENSITY RANGE C0.0-.025) MW/CM2
N
U
M
B
E
0
F
20000
19000
10000
A 17000-
U
16000 • -
15000 • -
14000
77*
15063
1
95*
16605
I
99*
9058 19622
19343
100* 100*
19676 19676
100*
1967


100 200 500 IK
DISTANCE


2K	5K
IN METERS

100*
19676
I

10K
20K
Figure B4-1. Number of assignments for broadcast stations which can produce power densities
between 0.0 and 0.025 mW/cm^.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PROCESSED®19B7S
POWER DENSITY RANGE C025-.05) MW/CM2
2000
N
U
M
B
E
R
0
F
A 1000
?
s
M
6
I
0
7%
1452
I
100
2%
309
I
IS
159
m
54
i/L kVf/i
0%
0
0*
0
200

500 IK 2K	5K
DISTANCE IN METERS
0*
0
—i—
10K
0*
0-
-+-
20K
Figure B4-2. Number of assignments for broadcast stations which can produce power
densities between 0.025 and 0.05 mW/cm2.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS-1967S
TOTAL NUMBER PR0CESSED=1967G
POWER DENSITY RANGE C.05-.13 MW/CM2
DISTANCE IN METERS
Figure B4-3. Number of assignments for broadcast stations which can produce power
densities between 0.05 and 0.1 mW/cm2.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=1967G
TOTAL NUMBER PROCE5SED-19G7S
POWER DENSITY RANGE C.1-.5J MW/CM2
700 r
600 -
N
U
M
B 500
R
F 400
A
S
G
N
M
T
S
300 ¦¦
200 ¦
100 ¦
0
3%
G7B

2%
344

0X
54
0%
0
0*
0
0%
4-
0X
0
0*
eu
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B4-4. Number of assignments for broadcast stations which can produce power
densities between 0.1 and 0.5 mW/cm .

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PR0CESSED=19676
POWER DENSITY RANGE C.5-1.0) MW/CM2
200 T
N
U
M
B
E
R
0
F
A
S
1
G
N
M
100 ¦
0
IX
170
I
0X
04
I
100 200
0*
a	t
0X
0
—+—
0X
0
0X
JL
0X
0
0X
0
500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B4-5. Number of assignments for broadcast stations which can produce power
densities between 0.5 and 1.0 mW/cm2.

-------
V0
o
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PROCESSED*19G76
POWER DENSITY" RANGE Cl.0-10.0) MW/CM2
300 r
200 -
A
S
S
I
G
M 100
0
100
0%
0
200
0X
0
500
058
0
—t—
IK
0X
0
1
2K
0%
0
—i—
5K
0X
0
10K
0*
20K
DISTANCE IN METERS
Figure B4-6. Number of assignments for broadcast stations which can produce power
densities between 1.0 and 10.0 mW/cm .

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS-039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY RANGE C0.0-.025) MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
470 r
460 •
450 •
440 •
430
420
410
400
99* 99* 99*
4 SB 460 4G0
05*
402
1
89*
420
1
390
94*
446
!
i j
95*
447
I
100 200 500 IK
DISTANCE



99*
460
I
2K	5K
IN METERS
10K
20K
Figure B5-1. Number of assignments for civilian fixed beam radar stations^which can
produce off-axis power densities between 0.0 and 0.025 mW/cm .

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF" ASSIGNMENTS=839
TOTAL NUMBER PR0CESSED=472
POWER DENSITY RANGE C.025-.05D MW/CM2
DISTANCE IN METERS
Figure B5-2. Number of assignments for civilian fixed beam radar stations which can
produce off-axis power densities between 0.025 and 0.05 mW/cm .

-------
30
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY RANGE C.05-.1) MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
20
10 •
0
2%
11
I
0X
0
0*
-4-
0*
0

0X
0
—I—
0*
0
-t-
035
0.

100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure B5-3. Number of assignments for civilian fixed beam radar stations which can
produce off-axis power densities between 0.05 and 0.1 mW/cm2.

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
POWER DENSITY RANGE C.1-.53 MW/CM2
30
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
20 •
10
0
5*
25
1
i

0*
1
Yzn
0*
0
0%
0
0*
0
0*
0
035
0.
100 200


500 IK	2K	5K
DISTANCE IN METERS
-+J
10K
20 K
Figure B5-4. Number of assignments for civilian fixed beam radar stations which
can produce off-axis power densities between 0.1 and 0.5 mW/cm2'

-------
30
CIVILIAN FIXED SEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS-B39
TOTAL NUMBER PROCESSED=472
POWER DENSITY RANGE C1.0-10.0J MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
20 ¦
10 •
0
4*
21
e%
0
0%
0
0%
0
0%
0
0*
0
035
-1.
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B5-5- Number of assignments for civilian fixed beam radar stations which can
produce off-axis power densities between 1.0 and 10.0 mW/cm^.

-------
CIVILIAN SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=594
TOTAL NUMBER PR0CESSED=593
POWER DENSITY RANGE C0.0-.0253 MW/CM2
594
N
U
M
B
R 593
0
F
A
S
S
H 592
E
N
T
S
591
99*
592
1

100* 100% 100%
593 593 593



100% 100%
593 593


100% 100%
593 593


100 200
500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure B6-1. Number of assignments for civilian scanning radar stations
which can produce off-axis power densities between 0.0 and 0.025 mW/cm .

-------
2
CIVILIAN SCANNING RADAR
TOTAL NUMBER OF ASSIGNKENTS=594
TOTAL NUMBER PR0CESSECN593
POWER DENSITY RANGE (.025-05) MW/CM2
N
U
M
B
E
R
0
F
A
S
5
1
G
N
M
6
I
1 ¦¦
0
0S
i
0%
0S
0%
0*
0X
035
0*
0
0
0
0
0
0
%
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure B6-2. Number of assignments for civilian scanning radar stations which
can produce off-axis power densities between 0.025 and 0.05 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED-300
POWER DENSITY RANGE C0.0-025) MW/CM2
300 T
290 ••
N
U
M
B 260
R
F 270
A
S
5
I
G
N
M
6
I
260
250 ¦
240 ¦
230
SIX
242
1
421
09*
2se
93*
270

94*
2G2
I
9E5K
2B9

99*
297
I
99*
290
99*
298


100 200 500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure B7-1. Number of assignments for military fixed beam radar stations which
can produce off-axis power densities between 0.0 and 0.025 mW/cm^.

-------
N
U
M
B
E
R
0
F
I
G
N
M
i
l
20
10
0
5*
14
1
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS-307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE C.025-.053 MW/CM2
IX
1
i00 200
IX
i
2X
6
0X
m
0X
m
0X
0
IX
i
500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B7-
2. Number of assignments for military fixed beam radar stations
which can produce off-axis power densities between 0.025 and 0.05 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE C.05-.13 MW/CM2
20
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
g
s
10 -
0
EX
10
I
100
3*
B
I
200
2%
6
I
0X
m
2%
I
05?
0
—i—
500 IK 2K	5K
DISTANCE IN METERS
0*
0
10K
0X
20K
Figure B7-3. Number of assignments for military fixed beam radar stations	^
which can produce off-axis power densities between 0.05 and 0.1 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS»307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE C.1-.5D MW/CM2
DISTANCE IN METERS
Figure B7-4. Number of assignments for military fixed beam radar stations
which can produce off-axis power densities between 0.1 and 0.5 mW/cm .

-------
4
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE C.5-1.03 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
N
M
§
I
2 ¦¦
i ¦
0
08
0
0*
Z%
0
1*

0*
0
0*
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure B7-5. Number of assignments for military fixed beam radar stations	^
which can produce off-axis power densities between 0.5 and 1.0 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE Cl.0-10.0) MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
8
7
G -
5 •
4
3
2
1
Z
2%
I
2%
2%
6
0%

IX
2
ex
0
0*
0
0X
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
I0K
20K
Figure B7-6. Number of assignments for military fixed beam radar stations	^
which can produce off-axis power densities between 1.0 and 10.0 mW/cm .

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
POWER DENSITY RANGE C10.0-INF) MW/CM2
N
U
M
B
E
R
0
F
A
5
S
1
G
N
M
5
5
0 T
7
B ¦
5
4 ••
2 ••
1 ¦
0
2%
0*
1
0%
0
0X
0
0*
0
0X
0
100 200 500	IK	2K
DISTANCE IN METERS
5K
10K
20K
Figure B7-7. Number of assignments for military fixed beam radar stations
which can produce off-axis power densities greater than 30.0 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS*1858
TOTAL NUMBER PR0CESSED=1G43
POWER DENSITY RANGE C0.0-025D MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
1050
1040
1030 ¦
1020 -
1010 •
1600 ¦
100% 100%
049 1049
1790
97*
1001
I
90%
1013

99*
99* 1843
1041



100*
1049
100 200 500 IK
DISTANCE

1
I.
100*
1049
I
A-
2K	5K
IN METERS
10K
20K
Figure B8-1. Number of assignments for military scanning radar stations	2
which can produce off-axis power densities betwe.en 0.0 and 0.025 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=i050
TOTAL NUMBER PR0CESSED=1649
POWER DENSITY RANGE C.025-.053 MW/CM2
DISTANCE IN METERS
Figure B8-2. Number of assignments for military scanning radar stations
which can produce off-axis power densities between 0.025 and 0.05 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1050
TOTAL NUMBER PROCESSED=1049
POWER DENSITY RANGE C.05-.13 MW/CM2
DISTANCE IN METERS
Figure B8-3. Number of assignments for military scanning radar stations which
can produce off-axis power densities between 0.05 and 0.1 mW/cm^.

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1850
TOTAL NUMBER PR0CESSED=1849
POWER DENSITY RANGE C.1-.53 MW/CM2
30 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
%
i
20 --
10
0
1%
26
I
0%
I
0%
6
0*
0
0%
0
0*
0
0X
0
0%
0
100 200
500 IK	2K	5K
DISTANCE IN METERS
10K
-+-
20K
Figure B8-4. Number of assignments for military scanning radar stations
which can produce off-axis power densities between 0.1 and 0.5 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1058
TOTAL NUMBER PROCESSED-1049
POWER DENSITY RANGE C.5-1.03 MW/CM2
N
U
M
B
E
R
0
F
A
S
G
N
M
I
I
6
7
6
5
4 ¦¦
3
2
1
0
0X
3

0%
0
-t-
0X
0
0X
0
—i—
0X
0
0*
0
0X
0,
100
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure B8-5. Number of assignments for military scanning radar stations	^
which can produce off-axis power densities between 0.5 and 1.0 mW/cm .

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1050
TOTAL NUMBER PR0CESSED=1649
POWER DENSITY RANGE Cl.0-10.03 MW/CM2
N
U
M
B
E
R
0
F
A
S
G
N
M
E
N
T
5
0 T
7 •
6 •
5 ¦¦
4 ¦¦
3 ¦¦
2
0
0%
I
0%
0
0%
0
0%
0
056
0
—t—
2K
0X
0
1
5K
0X
0
0*
0
—(-«—
20K
100
200
500
IK
10K
DISTANCE IN METERS
Figure B8-6. Number of assignments for military scanning radar stations
which can produce off-axis power densities between 1.0 and 10.0 mW/cm .

-------
EARTH STATIONS CMAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C0.0-.025) MW/CM2
N
U
M
B
E
R
1100 •
1000 ¦
900
600
600 •
0
F 700
A
S
S
1
G
M 500
E
N
T
S
400 ¦¦
300 •
200
24%
363
s
29*
436
S
36%
540
I
39*
595

43*
653

50*
755
i
100 200 500 IK
DISTANCE
65*
970
I
2K	5K
IN METERS
69*
1034

10K 20K
Figure B9-1. Number of assignments for earth stations which can	2
produce mainbeam power densities between 0.0 and 0.025 mW/cm .

-------
EARTH STATIONS CMAINBEAM5
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.05-.13 MW/CM2
300
N
V
H
B
E
R
0
F
200 •
A
S
S
I
G
100
E
N
T
S
0
10%
150

11%
170
!
10%
9* *58
143


e«
119
I
100 200 500 IK
DISTANCE
19*
204
7*
102
I
2K	5K
IN METERS
10K
20K
Figure B9-2. Number of assignments for earth stations which
can produce mainbeam power densities between 0.05 and 0.1 mtf/cra2.

-------
EARTH STATIONS CMAINBEAM3
TOTAL NUMBER OF ASSIGNMENrS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.025-.053 MW/CM2
N
U
M
B
E
R
0
F
A
S
N
M
i
l
100 T
90 ¦
00 ¦¦
70 ¦
60 -
50 •
40
30
4*
65
4X
61
1
4SK
54
I
3%
42
6X
90
I
3*
43
3X
52
I
|J
1 I
5X
02
!
I
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B9-3. Number of assignments for earth stations which can	^
produce mainbeam power densities between 0.025 and 0.05 mW/cm .

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.1-.5) MW/CM2
500 T
N
U
M 400
B
E
R
0
F
A 300
S
1
G
N
M
E
!jj 200
100
21*
318
I

19$	19*
262 16* 293
269



29*
410

i
1 I
14*
210
1
100 200 500 IK
DISTANCE
i
23*
341

2K	5K
IN METERS
17*
250
10K 20K
Figure B9-4. Number of assignments for earth stations which can
produce mainbeam power densities between 0.1 and 0.5 mW/cm .

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS-1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.5-1.03 MW/CM2
200
N
U
M
B
E
R
0
F
A 100
G
N
M
E
N
T
S
0
11*
159

BX
126
!
1156
170
I
ex
122

758
108
i
3%
132
1
3X
42
I
IX
B
Y7fr
100 200 500 IK
DISTANCE
2K	5K
IN METERS
10K
20K
Figure B9-5. Number of assignments for earth stations which can	^
produce mainbeam power densities between 0.5 and 1.0 mW/cm .

-------
400 T
EARTH STATIONS CMATNBEAM3
TOTAL NUMBER OF ASSIGNMENTS-1503
TOTAL NUMBER PROCESSEO=1509
POWER DENSITY RANGE Ci.0-10.03 MW/CM2
N
U
M 300
B
E
R
21%
314
0
F
A
5
S
1
G
N
M
E
N
T
S
200
100
0
11*
161
14*
209

19*
293
68
97
I
595
70
2%
23
JL
10K
1*
14
-251
100 200 50g ik	2K	5K
DISTANCE IN METERS
20K
Figure B9-6. Number of assignments for earth stations which can	^
produce mainbeam power densities between 1.0 and 10.0 mW/cm .

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=i509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C10.0-INF) MW/CM2
300 r
N
U
M
B
E
R
0
F
A
S
1
G
H 100
E
I
200 +
0
1955
290
I
15*
223
I
1* IX IX IX
16	14	IB	15
w	w	m	m.
IX
12
m.
100 200 500 IK	2K	5K
DISTANCE IN METERS
IX
11
10K
20K
Figure B9-7. Number of assignments for earth stations which can	2
produce mainbeam power densities greater than 10.0 mW/cm .

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C0.0-0253 MW/CM2
1500 r
1400
1300 •
K1
U
M
B
E
R
0
F
* 1200
S
I
G
fj 1100
E
N
T
S
1000 I
S00
71%
1076

76*
1144
I
el*
1217

94 SK
1425

95*
1436

I
98*
14 76
V.

100 200 500	IK
DISTANCE

ge*
1463
99*
1497

2K	5K
IN METERS
10K

i
20K
Figure BlO-1. Number of assignments for earth stations which can produce
off-axis power densities between 0.0 and 0.025 mW/cm2.

-------
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.025-.05) MW/CM2
B%
DISTANCE IN METERS
Figure B10-2. Number of assignments for earth stations which can
produce off-axis power densities between 0.025 and 0.05 mW/cm .

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSEQ=1509
POWER DENSITY RANGE C.05-.1) MW/CM2
300
DISTANCE IN METERS
Figure BlO-3. Number of assignments for earth stations which can	^
produce off-axis power densities between 0.05 and 0.1 mW/ctti .

-------
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.1-.5D MW/CH2
300 T
N
U
H
B
| 200
0
F
A
S
S
I
G
N
M
E
N
T
S
100
0
14*
214
I
100 200
0X
6
w (/\
0*
3
0X
4
0%
6
0X
3
0%
2
500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure B10-4.
Number of assignments for earth stations which can	^
produce off-axis power densities between 0.1 and 0.5 mW/cm .

-------
7 T
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C.5-1.0D MW/CM2
H
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
B ¦¦
5 ¦
3
1 ••
0
0%
i
0%
a
z%
l
0%
i
1 I
0%
z
0%
0
0%
I
100 200 500 IK	2K
DISTANCE IN METERS
5K
10K
20K
Figure BlO-5. Number of assignments for earth stations which can
produce off-axis power densities between 0.5 and 1.0 mW/cm .

-------
4
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE Cl.0-10.03 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
0%
0%
3
2
1
0
0%

0%



0%

0%
0
0%
i
0%
0.
100 200
500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure BlO-6. Number of assignments for earth stations which can	2
produce off-axis power densities between 1.0 and 10.0 mW/cm .

-------
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=i509
TOTAL NUMBER PROCESSED=1509
POWER DENSITY RANGE C10.0-INF] MW/CM2
11 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
10 ••
9
0 -
1*
10
V.
ias
10
r

is
$
I
l*

I*

1%
i
P
I i


1*
e
i
1J5
8
i
100 200
500 IK
DISTANCE
2K	5K
IN METERS
10K 20K
Figure B1G-7. Number of assignments for earth stations which can
produce off-axis power densities greater than 10.0 mW/cm .

-------
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF ASSIGNMENTS-174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY RANGE C0.0-.025) MW/CM2
200 T
N
U
M
B
E
R
0
F
A
S
5
1
G
N
M
6
S
100 +
0
13*
22
1
53*
93
!
B7%
116

90%
157
I
100% 100%
174 174
I 1

IB

2K	5K
IN METERS
100% 100%
174 174
I
n
100 200 500 IK
DISTANCE
10K 20K
Figure Bll-1. Number of assignments for other stations (10kHz to 100kHz) ^
which can produce power densities between 0.0 and 0.025 mW/cm .

-------
60
OTHER STATIONS C10 KHZ TO 100 KHZ3
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY RANGE C.025-.053 MW/CM2
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
70
G0
50 ¦¦
40
30
20
10
0
22%
39
!
0*
0
Z%
0
0*
0
0X
0
100 200 500 IK	2K
DISTANCE IN METERS
5K
10K
23K
Figure Bll-2. Number of assignments for other stations {10kHz to 100kHz)
which can produce power densities between 0.025 and 0.05 mW/cm2.

-------
40 T
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY RANGE C.05-.I5 MW/CM2
N
U
M
B
E
R
0
F
I
G
N
M
i
s
30
20
10 ••
0
11*
19
I
0«
0
0*
0
0*
0
100 200 500 IK 2K	5K
DISTANCE IN METERS
0ft
0
0ft
10K
20K
Figure Bll-3. Number of assignments for other stations (10kHz to 100kHz) ^
which can produce power densities between 0.05 and 0.1 mW/cm .

-------
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
POWER DENSITY RANGE C.1-.53 MW/CM2
N
U
M
B
E
R
0
F
A
S
G
N
M
E
N
T
S
70 r
60 -
50
40 ¦¦
30
20 ¦¦
10 ¦
0
37X
65
I
100
16%
20
I
200
0X
0
—t—
0%
0
1
IK
0%
0
500 IK	2K
DISTANCE IN METERS
0X
0
—t—
5K
0X
0
—i—
10K
0X
JU
20K
Figure Bll-4. Number of assignments for other stations (10kHz to 100kHz)
which can produce power densities between 0.1 and 0.5 mW/cm .

-------
OTHER STATIONS C100 KHZ TO 30561 KHZ}
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
POWER DENSITY RANGE C0.0-.025) MW/CM2
11000 T
10000 •
N
U
M 9000
B
E
R
0
F
A
S
G000
7000
G 6000
M
| 5000
S
4000
3000
99%
97* 10705
10536
99* 99%
10B05 10907
100% 10058
1090B 10900
04*
9106
I


100 200 500 IK
DISTANCE




2K	5K
IN METERS
10K 20K
Figure B12-1. Number of assignments for other stations (100kHz to 30561kHz)2
which can produce power densities between 0.0 and 0.025 mW/cm .

-------
OTHER STATIONS Ci00 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=1090B
TOTAL NUMBER PROCESSED=10900
POWER DENSITY RANGE C025-.05D MW/CM2
Figure B12-2. Number of assignments for other stations (100kHz to 30561kHz)
which can produce power densities between 0.025 and 0.05 mW/cm2.

-------
900 T
600 -
OTHER STATIONS C100 KHZ TO 30561 KHZ5
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED-10900
POWER DENSITY RANGE C.05-.13 MW/CM2
N
U 700
M
B
E
R
0
F
600 -
500 -
S 400
I
G
(j 300
i
T 200 •
100 -
0
0*
23
JE32L
IX
66
Z%
9
0*
1
0X
0
—K—
100 200 500 IK	2K
DISTANCE IN METERS
5K
10K
0X
20K
Figure B12-3. Number of assignments for other stations (100kHz to 30561kHz)
which can produce power densities between 0.05 and 0.1 mW/cm2.

-------
OTHER STATIONS C100 KHZ TO 305B1 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=1090B
TOTAL NUMBER PROCESSED*10900
POWER DENSITY RANGE C.1-.53 MW/CM2
DISTANCE IN METERS
Figure B12-4. Number of assignments for other stations (100kHz to 30561kHz)
which can produce power densities between 0.1 and 0.5 mW/cm2.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZD
TOTAL NUMBER OF ASSIGNMENTS=10908
TOTAL NUMBER PROCESSED®10900
POWER DENSITY RANGE C.5-1.03 MW/CM2
400
N
U
M 300
B
E
R
0
F
A
S
5
1
N
M
6
I
200 ••
100
0
0%
36
22 30
100 200
0%
19
M-
500 IK	2K	5K
DISTANCE IN METERS
0*
0
—+—
0X
0
—t—
0%
0
—t—
0*
0
1
10K
0%
20K
Figure B12-5.
Number of assignments for other stations (100kHz to 30561kHz)
which can produce power densities between 0.5 and 1.0 mW/cm^.

-------
5 T
OTHER STATIONS C100 KHZ TO 30561 KHZ3
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
POWER DENSITY RANGE C10.0-INF] MW/CM2
N
U
M
Q
E
R
0
F
4 -
3 ••
A
S
S
I
G
N
M
2 ¦
T
S
i ¦
0
0*
0
0*
0
0*
0
—i—
2K
0*
0
—t—
5K
0*
0
0
—t-
100
200
500
IK
10K
20K
DISTANCE IN METERS
Figure B12-
6.
Number of assignments for other stations {100kHz to 30561kHz)
which can produce power densities greater than 10.0 mW/cm2.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF AS5IGNMENTS=127
TOTAL NUMBER PROCESSED-127
POWER DENSITY RANGE C0.0-.0253 MW/CM2
130 ¦
120 ¦
N
U
B 100 f
E
R
0
F
30 ¦
80 -
70
N t
M
^ 50 -
S 40 •
30 •
20
24%
31
n
38*
70S
99

92%
117
I
92%
117
I
90*
124
I
90S
125
I
100*
127

100 200 500 IK
DISTANCE
2K 5K
IN METERS
10K 20K
Figure B13-1. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities between 0.0 and 0.025 mW/cm^

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ3
TOTAL NUMBER OF ASSIGNMENTS-127
TOTAL NUMBER PR0CESSED=127
POWER DENSITY RANGE C.025-.05D MW/CM2
20 T
13*
17
N
U
M
B
E
R
0
F
A
5
s
1
G
N
M
6
I
10 ¦
0
10*
13
i
12%
15

1 1


056
0
5*
6
IX

0%
-Su-
20K
100 200 500 IK 2K 5K
DISTANCE IN METERS
10K
Figure B13-2. Number of assignments for other stations (30.561MHz to 960MHz)2
which can produce power densities between 0.025 and 0.05 mW/cm .

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED=127
POWER DENSITY RANGE C.05-.1) MW/CM2
40
N
U
M
B
E
R
0
F
A
S
s
1
N
M
E
¥
S
30
20 ¦
10 ¦¦
0
3%
1
IS
1
P77I
Z%
0
IX
1
[7771
0«
0
0K
0
0X
0
500
IK
2K
5K
10K
20K
100
200
DISTANCE IN METERS
Figure B13-3. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities between 0.05 and 0.1 mW/cm^.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED=127
POWER DENSITY RANGE C.1-.53 MW/CM2
DISTANCE IN METERS
Figure B13-4. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities between 0.1 and 0.5 mW/cm2.

-------
30
OTHER STATIONS (30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
POWER DENSITY RANGE (.5-1.0) MW/CM2
N
U
M
B
E
R
0
F
I
G
M
6
I
20
10 •
0
17*
21
I
5S
6
0*
P
IX
1
7771
0X
0
0*
0
0%
?
Z%
0.
200
500
IK
2K
5K
10K
20K
DISTANCE IN METERS
Figure B13-5. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities between 0.5 and 1.0 mW/cm^.

-------
OTHER STATIONS C30.56JL MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=*127
TOTAL NUMBER PR0CESSED=127
POWER DENSITY RANGE Cl.0-10.03 MW/CM2
N
U
M
B
E
R
0
F
A
S
S
N
M
T
S
9 T
0
7 ¦
5 ¦
A ¦¦
3 ••
2
1
656
i
6*
B

2%
2
i
2%
1
2%

Z%
0
0X
0
-t-
0X
0.
-t-
20K
100 200 500 IK 2K 5K
DISTANCE IN METERS
10K
Figure B13-6. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities between 1.0 and 10.0 mW/cm^.

-------
5
OTHER STATIONS C30.5S1 MHZ TO 960 MHZ5
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
POWER DENSITY RANGE C10.0-INR MW/CM2
4
3 ¦ ¦
2
1 •
0
3%
4

2%
i
2%

0*
0
0%
0
0K
0
100 200 500 IK	2K	5K
DISTANCE IN METERS
0*
0
—4—
0X
-Z-
10K
20K
Figure B13-7. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce power densities greater than 10.0 mW/cm2.

-------
OTHER STATIONS (960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PRXESSED-299
POWER DENSITY RANGE CC.0-.025J MW/CM2
300 r
N
If
M
B
| 200
0
F
A
S
S
1
G
\\ 100
E
N
0
41
12
YZ&.
53*
150
1
I
100 200
51*
152
1
1
57*
53* 54* 170
156 160
I
500 IK
DISTANCE

A
2K	5K
IN METERS
est
257
1
92%
274
I
10K 20K
Figure B14-1. Number of assignments for other stations (960MHz and above)
which can produce power densities between 0.0 and 0.025 mW/cm .

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
POWER DENSITY RANGE C.025-.05) MW/CM2
N
U
M
B
E
R
0
F
A
S
G
N
M
90
80 -
70
60
50
40
30
20
10 -
0
IX
2
i*
Y%L
0X
0
IX
2
20X
59
!
5X
15
1
IX
2
cq»7l
100 200 500 IK 2K 5K
DISTANCE IN METERS
10K
20K
Figure B14-2. Number of assignments for other stations (960MHz and above) ^
which can produce power densities between 0.025 and 0.05 mW/cm .

-------
OTHER STATIONS C9G0 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PROCESSED-299
POWER DENSITY RANGE C.05-1) MW/CM2
DISTANCE IN METERS
Figure B14-3. Number of assignments for other stations (960MHz and above) ^
which can produce power densities between 0.05 and 0.1 mW/cm .

-------
OTHER STATIONS C960 MHZ AND ABOVE3
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
POWER DENSITY RANGE C.1-.53 MW/CM2
90 ¦
B0 -
N
U 70 +
M
B
| <50
?
A
S
T
S
50 ¦
40 ¦¦
G
M 30f
20
10
0
0%
i
2%
6
m
IX
2
7771
3%
B
1
30*
69
I
6*
16
1
2%
6
0X
1
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B14-4. Number of assignments for other stations (960MHz and above)^
which can produce power densities between 0.1 and 0.5 mW/cm .

-------
OTHER STATIONS C960 MHZ AND ABOVE5
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSE0=299
POWER DENSITY RANGE C.5-1.0) MW/CM2
N
U
M
B
E
R
0
F
A
S
S
N
M
T
S
60 T
50
40 ¦
30
20
10 -
IX
A
0
0*
-2-
2*
5
1
18X
53
I
558
15
0X
1
iJf A
0*
1
At fit
0X
JL
100 200 500 IK	2K	5K
DISTANCE IN METERS
10K
20K
Figure B14-5. Number of assignments for other stations (960MHz and above)
which can produce power densities between 0.5 and 1.0 mW/cm .

-------
OTHER STATIONS C960 MHZ AND ABOVE?
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSED=299
POWER DENSITY RANGE (1.0-10.0) MW/CM2
DISTANCE IN METERS
Figure B14-6. Number of assignments for other stations (960MHz and above) 2
which can produce power densities between 1.0 and 10.0 mW/cm .

-------
OTHER STATIONS C9S0 MHZ AND ABOVE]
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSED=299
POWER DENSITY RANGE C10.0-INF) MW/CM2
200
100 200 500 IK	2K	5K 10* 20K
DISTANCE IN METERS
Figure B14-7. Number of assignments for other stations (96QMHz and above)
which can produce power densities greater than 10.0 mW/cm .

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=3629i
TOTAL NUMBER PROCESSED-35907
POWER DENSITY RANGE C0.0-.0253 MW/CM2
40000
N
U
M
B
| 30000
0
F
5
N
20000 •
10000
65*
23359
I
90S
32320

99%
96* 35429
34621


99* 99*
35647 35734
100 200
500 IK
DISTANCE


99* 99*
35031 35064


2K 5K
IN METERS
10K 20K
Figure B15-1. Number of assignments for stations which can produce
power densities between 0.0 and 0.025 mW/cm^.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAH3
TOTAL NUMBER OF ASSIGNMENTS=3B29i
TOTAL NUMBER PROCESSED-35907
POWER DENSITY RANGE C.025-.05) MW/CM2
6000
5000
N
U
M
B
r 4000
0
F
A 3000
S
1
G
fj 2000
6
s
1000
0
17*
5965

IX
499
H
100 200
0X
167
VTA
0*
74
0X
79
500 IK	2K	5K
DISTANCE IN METERS
0X
29
i
0*
5.
10K
20K
Figure B15-2. Number of assignments for stations which
can produce power densities between 0.025 and 0.05 mW/cm .

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS»36291
TOTAL NUMBER PROCESSEO-35907
POWER DENSITY RANGE C.05-.1) MW/CM2
DISTANCE IN METERS
Figure B15-3. Number of assignments for stations which can	^
produce power densities between 0.05 and 0.1 mW/cm .

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAMD
TOTAL NUMBER OF ASSIGNMENTS=3629i
TOTAL NUMBER PROCESSED-35907
POWER DENSITY RANGE C.1-.5D MW/CM2
DISTANCE IN METERS
Figure B15-4. Number of assignments for stations which can
produce power densities between 0.1 and 0.5 mW/cm .

-------
EARTH STATIONS (MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED-1509
DISTANCE FROM ANTENNA 1000 METERS
1000
900
N
U
M
B
E
R
0 600
F
A
S
S
I
G
N
M
E
¥
000
700
500
400
300
200
100
0
Gil
914
I
.025
50%
872
I
47*
714
29%
431
i
20*
309
i
.05
MINIMUM
.1	.5	1
POWER DENSITY IN MW/CM2
1%
IB
10
Figure C9-4. Number of assignments for earth stations which can produce
specified mainbeam power densities at 1,000 meters.

-------
EARTH STATIONS CMAINBEAMD
TOTAL NUMBER OF ASSIGNMENT5=1509
TOTAL NUMBER PROCESSEQ=1509
DISTANCE FROM ANTENNA 2000 METERS
900 T
600
N
U 700
M
B
E
R
B00
0
F 500
A
S
S
1
c
N
M
E
N
T
S
400 -¦
300
200 -
100 -
0
57*
656
.025
50*
758

42%
639


151
221
i
7%
113
1
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
IX
16
10
Figure C9-5. Number of assignments for earth stations which can produce
specified mainbeam power densities at 2,000 meters.

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED-1509
DISTANCE FROM ANTENNA 5000 METERS
000 T
700 +
N
M 600
B
E
R
0
F
A
S
S
N
500 +
400 +
300 +
N 200
100 +
0
50*
754
I
47*
711
1
I
I
28%
427
14*
217
I
6*
85
1
1*
15
17771
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C9-6. Number of assignments for earth stations which can produce
specified mainbeam power densities at 5,000 meters.

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 10000 METERS
600 r
500 -
N
U
M
8
r 400
0
F
A 300
N
!:
N
T
S
200 --
100 •
0
35*
531
I
3 2%
473

2Q%
410
P
I I
5*
77
1
2%
35
IS
12
P77I.
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MV//CM2
10
Figure C9-7. Number of assignments for earth stations which can produce specified mainbeam
power densities at 10,000 meters-

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENT5=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 20000 METERS
N
U
M
B
E
R
0
F
J
£
M
E
N
T
S
500 T
400 +
300 f
200 +
100 +
0
SIX
475
I
.025
26*
393
I
19*
291
i
2%
33
2*
25
m
IX
n
JZ?2L
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C9-8. Number of assignments for earth stations which can produce specified
mainbeam power densities at 20,000 meters.

-------
EARTH STATIONS COFF-AXISD
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 100 METERS
500 T
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
400 ••
300 ¦¦
200
100 ••
0
29515
433
V.


20%
295
Vj

I
1*
10
YZZL
IX
12
7J7S.
1%
10
17771
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C10-1. Number of assignments for earth stations which can produce
specified off-axis power densities at 100 meters.

-------
400 T
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
300
200 ¦¦
100 •
0
10SS
260
15*
227
IX
13
VZ7i
1%
12
K/f/1
IS
10
.5
1
10
.025
.05
.1
MINIMUM POWER DENSITY IN MW/CM2
Figure ClO-2. Number of assignments for earth stations which can produce specified
off-axis power densities at 200 meters.

-------
EARTH STATIONS COFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 500 METERS
300 T
200 ¦¦
100 ¦
19%
292
I
1GX
240
I

IX
19
IX
13
EZL
IX
12
YZZl
IX
9
Yff\
.025
•05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure CI0-3. Number of assignments for earth stations which can produce
specified off-axis power densities at 500 meters.

-------
EARTH STATIONS COFF-AXIS5
TOTAL NUMBER OF ASSIGNMENTS*1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 1000 PETERS
N
U
M
B
E
R
0
F
A
S
G
N
M
E
N
T
S
90
80
70
60
50
40
30
20
10
0
G%
84
1
4X
53
IX
IS
i
IX
13
I
IX
12
1
IX
9
P77
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C10-4. Number of assignments for earth stations which can produce specified
off-axis power densities at 1,000 meters.

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 2000 METERS
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
00
70 ¦¦
60 ¦¦
50
40
30
20
10
0
535
73
I
1

IS!
11
i
IS
9
i
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure CI0-5. Number of assignments for earth stations which can produce
specified off-axis power densities at 2,000 meters.

-------
EARTH STATIONS COFF-AXIS3
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 5000 METERS
40
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
30
20 ¦¦
10
0
2X
33
I
.025
1*
15
I
IX
15
1
1%
I
IX
9
£2
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
IX
9
M
10
Figure C10-6. Number of assignments for earth stations which can produce
specified off-axis power densities at 5,000 meters.

-------
EARTH STATIONS (OFF-AXIS)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 10000 METERS
30 T
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
20 ••
10 ¦¦
0
2%
26
I

i

.025
1*
14

1*
12

1*
9

IX
9

I
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
IX
8
¦
10
Figure ClO-7. Number of assignments for earth stations which can produce
specified off-axis power densities at 10,000 meters.

-------
13 T
EARTH STATIONS COFF-AXISD
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 20000 METERS
N
U
M
B
E
R
0
F
A
5
S
1
G
N
M
E
N
T
S
12
11
10 ••
9
8 ¦
1%
12
i
IX
11
i
IX
11
I
IX
9

IX
8
¦
•IX
8
1
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C10-8. Number of assignments for earth stations which can produce
specified off-axis power densities at 20,000 meters.

-------
OTHER STATIONS C10 KHZ TO 100 KHZ5
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
DISTANCE FROM ANTENNA 100 METERS
200 T
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
100
0
07*
152
I
47*
ei
i
37*
65
s
0%
4-
0%
0
-+-
0*
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure Cll-1. Number of assignments for other stations (10kHz to 100kHz) which
can produce specified power densities at 100 meters.

-------
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
DISTANCE FROM ANTENNA 200 METERS
90
00
N
U 70
M
e
I 60
P	50
A
^	40 ¦¦
S	30 ¦
i
I 20
10
0 •-
37*
65

0X
0
0X
0
—I—
0*
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure Cll-2. Number of assignments for other stations (10kHz to 100kHz) which
can produce specified power densities at 200 meters.

-------
OTHER STATIONS C10 KHZ TO 100 KHZ)
TOTAL NUMBER OF AS5IGNMENTS=174
TOTAL NUMBER PR0CESSED=174
DISTANCE FROM ANTENNA 500 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure Cll-3. Number of assignments for other stations (10kHz to 100kHz) which
can produce specified power densities at 500 meters.

-------
OTHER STATIONS C10 KHZ TO 100 KHZ3
TOTAL NUMBER OF ASSIGNMENTS=174
TOTAL NUMBER PR0CESSED=174
DISTANCE FROM ANTENNA 1000 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure Cll-4. Number of assignments for other stations (10kHz to 100kHz) which
can produce specified power densities at 1,000 meters.

-------
7000
OTHER STATIONS C100 KHZ TO 305G1 KHZ5
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
DISTANCE FROM ANTENNA 100 METERS
6000
N
U
M
B 5000
R
F 4000
A
S
s
I
G
N
M
E
N
T
S
3000 • -
2000
1000 --
0
.025
23%
2531
4*
422
IX
09
0%
4
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C12-1. Number of assignments for other stations (100kHz to 30561kHz)
which can produce specified power densities at 100 meters.

-------
to
H
W
OTHER STATIONS (100 KHZ TO 30561 KHZD
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
DISTANCE FROM ANTENNA 200 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C12-2. Number of assignments for other stations (100kHz to 30561kHz)
which can produce specified power densities at 200 meters.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZJ
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSED=10900
DISTANCE FROM ANTENNA 500 PETERS
400
N
M 300
B
E
R
0
F
A 200 +
S
1
G
N
M
E
N 100
S
0
3%
372
I
L%
140

1*
117
I
0%
20
m.
0X
1
0*
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C12-3. Number of assignments for other stations (100kHz to 30561kHz)
which can produce specified power densities at 500 meters.

-------
OTHER STATIONS C100 KHZ TO 30561 KHZ)
TOTAL NUMBER OF ASSIGNMENTS=10908
TOTAL NUMBER PROCESSED-1090G
DISTANCE FROM ANTENNA 1000 METERS
200 T
IX
123
IX
91
0X
23
I
0X
1
0%
1
0X
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C12-4. Number of assignments for other stations (100kHz to 30561kHz)
which can produce specified power densities at 1,000 meters.

-------
NJ
(-»

-------
2
OTHER STATIONS C100 KHZ TO 30561 KHZ3
TOTAL NUMBER OF ASSIGNMENTS=10900
TOTAL NUMBER PROCESSEO1090B
DISTANCE FROM ANTENNA 5000 METERS
N
U
M
B
E
R
0
F
A
5
S
1
G
N
M
E
I
1 ¦
0
0X
I
0*
0X
0%
0X
0
0
0
0
.1
.5
1
10
POWER
DENSITY IN
MW/CM2

.025
Figure C12-6. Number of assignments for other stations (100kHz to 30561kHz) which
can produce specified power densities at 5,000 meters.

-------
OTHER STATIONS C30.5G1 MHZ TO 960 MHZ1
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED=127
DISTANCE FROM ANTENNA 100 METERS
N
U
M
B
E
R
0
F
A
S
S
1
C
N
M
E
N
T
S
100 T
90
60
70
60
50
40
30
20
10
76%
96

65*
63
1
62%
79
I
25%
32
.
935
11
3X
4
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C13-1. Number of assignments for other stations (30.561MHz to 960MHz) which
can produce specified power densities at 100 meters.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A
S
1
G
N
M
90
70
60
50
40
30 •
20
10 -
0
62%
79
50%
64
I
26%
33
0%
10

6%
10
0
2%
2
P771
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C13-2.
Number of assignments for other stations {30.561MHz to 960MHz)
which can produce specified power densities at 200 meters.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED«127
DISTANCE FROM ANTENNA 500 METERS
30 T
N
U
M
B
E
R
0
F
A
S
S
1
§
g
N
T
S
20 -
10 ¦
0
22%
28
1
9%
11
I
8*
10
1
ex
10
i

3*
4
2%
2
a_*
.025
•05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C13-3. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce specified power densities at 500 meters.

-------
OTHER STATIONS C30.5B1 MHZ TO 9G0 MHZ3
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PROCESSED-127
DISTANCE FROM ANTENNA 1000 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C13-4. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce specified power densities at 1,000 meters.

-------
OTHER STATIONS C30.561 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=i27
TOTAL NUMBER PROCESSED-127
DISTANCE FROM ANTENNA 2000 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C13-5. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce specified power densities at 2,000 meters.

-------
4
OTHER STATIONS C30.5B1 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED«127
DISTANCE FROM ANTENNA 5000 METERS
N
U
M
B
E
R
0
F
A
S
N
M
3
2
1
0
2%
!
2%

2%

0*
jl
0X
0
0X
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C13-6. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce specified power densities at 5,000 meters.

-------
3
OTHER STATIONS C30.5B1 MHZ TO 960 MHZ)
TOTAL NUMBER OF ASSIGNMENTS=127
TOTAL NUMBER PR0CESSED-127
DISTANCE FROM ANTENNA 10000 METERS
N
U
M
B
E
R
0
F
2 ¦
A
S
S
I
G
N
M
f
S
1
0
0%
0
m
0
0*
0%
0K
0
0
0
.5
1
10
.025
.05	.1
MINIMUM POWER DENSITY IN MW/CM2
Figure C13-7. Number of assignments for other stations (30.561MHz to 960MHz)
which can produce specified power densities at 10,000 meters.

-------
OTHER STATIONS C9B0 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
OISTANCE FROM ANTENNA 100 METERS
300
N
U
M
B
E
R
0
F
I
G
N
200 -
100 •
0
96*
207
66S
190
i
49X
140
i

40*
143
49%
147
1 .


46*
137
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C14-1. Number of assignments for other stations (960MHz and above) which
can produce specified power densities at 100 meters.

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PROCESSED-299
DISTANCE FROM ANTENNA 200 METERS
150 r
50*
149
N
U
M
B
E
R
0
F
140
A
S
5
I
G
M 130
6
I
120

49*
147

49*
147
I
47*
141
I
47*
141
!
43*
130
i
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C14-2. Number of assignments for other stations (960MHz and above) which
can produce specified power densities at 200 meters.

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PROCESSED-299
DISTANCE FROM ANTENNA 500 METERS
200 T
.025	.05	.1	.5	1	10
MINIMUM POWER DENSITY IN MW/CM2
Figure C14-3. Number of assignments for other stations (960MHz and above)
which can produce specified power densities at 500 meters.

-------
OTHER STATIONS C960 MHZ AND ABOVEJ
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSED-299
DISTANCE FROM ANTENNA 1000 METERS
200
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
100
0
47*
141
i
47*
141

46*
139
i
44*
131
I
26*
70
i
0*
25
a
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C14-4. Number of assignments for other stations (960MHz and above)
which can produce specified power densities at 1,000 meters.

-------
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS-299
TOTAL NUMBER PROCESSED-299
DISTANCE FROM ANTENNA 2000 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C14-5. Number of assignments for other stations (960MHz and above) which
can produce specified power densities at 2,000 meters.

-------
200 T
N
U
M
B
E
R
0
F
A 100 ¦¦
OTHER STATIONS C9G0 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGWENTS=299
TOTAL NUMBER PROCESSED-299
DISTANCE FROM ANTENNA 5000 METERS
I
G
N
M
5
s
0
.025
148
42
i
8*
24
Q%
23
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
G*
10
I I i
10
Figure C14-6. Number of assignments for other stations (960MHz and above)
which can produce specified power densities at 5,000 meters.

-------
50 T
OTHER STATIONS C960 MHZ AND ABOVE)
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PROCESSED-299
DISTANCE FROM ANTENNA 10000 METERS
N
U
M
B
E
R
0
F
a
40 ¦
30 ¦¦
i 20
10 ••
0
14*
42
I
9*
27
i
ex
25

6*
19

6%
16
I
2*
5
1
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C14-7. Number of assignments for other stations (960MHz and above)
which can produce specified power densities at 10,000 meters.

-------
OTHER STATIONS C960 MHZ AND ABOVE5
TOTAL NUMBER OF ASSIGNMENTS=299
TOTAL NUMBER PR0CESSED=299
DISTANCE FROM ANTENNA 20000 METERS
30
N
U
M
B
E
R
0
F
A
S
N
M
6
I
20
10 •
0
6%
25
I
ex
23
I
6X
19

ex
10

ex
le
I
IX
3
1
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C14-8. Number of assignments for other stations (960MHz and above)
which can produce specified power densities at 20,000 meters.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAW
TOTAL NUMBER OF ASSIGNMENTS=3629i
TOTAL NUMBER PROCESSED-35907
DISTANCE FROM ANTEMsIA 100 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C15-1. Number of assignments for stations which can produce specified
power densities at 100 meters.

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
DISTANCE FROM ANTENNA 200 METERS
4000
N
M 3000
e
E
R
0
F
A
S
S
I
G
N
M
E
I
2000 ¦
1000 -
0 -l-
10*
3503
.025
4%
1403
I
IX
302
IX
249
777.249
	M
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0X
145
&ZL
10
Figure C15-2. Number of assignments for stations which can produce specified
power densities at 200 meters.

-------
2000
COMPOSITE (.EXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSECN35907
DISTANCE FROM ANTENNA 500 METERS
N
U
M
B
R
?
A 1000
N
a
I
s
e
4*
1262
! -
%	703
1 1

.025

IX
302
1%
190
4mm
0*
159
0ff
55
V&I
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C15-3. Number of assignments for stations which can produce specified
power densities at 500 meters.

-------
500 T
COMPOSITE CEXCEPT EARTH STATIONS HAINBEAM5
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
DISTANCE FROM ANTENNA 1000 METERS
N 400
M
B
E
R
0 300
F
A
S
S
N
M
I
200
100 -
0
IX
199
0X
95
1
0X
35
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C15-4. Number of assignments for stations which can produce
specified power densities at 1,000 meters.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNHENTS=3G291
TOTAL NUMBER PROCESSED-35907
DISTANCE FROM ANTENNA 2000 METERS
300
N
U
M
B
| 200
A
S
M 100
0
IX
256
I
.025
IX
162
0X
154
1
0X
42
J
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0X
56
I
0X
20
(A.
10
Figure C15-5. Number of assignments for stations which can produce
specified power densities at 2,000 meters-

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=3G291
TOTAL NUMBER PROCESSED-35907
DISTANCE FROM ANTENNA 5000 METERS
200 T
100
0
0*
169

0X
90
i
0*
El
0X
35
0S
32
1
Z%
27
1
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C15-6. Number of assignments for stations which can produce
specified power densities at 5,000 meters.

-------
COMPOSITE (EXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=3G291
TOTAL NUMBER PROCESSED"35907
DISTANCE FROM ANTENNA 10200 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C15-7. Number of assignments for stations which can produce
specified power densities at 10,000 meters.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM3
TOTAL NUMBER OF ASSIGNMENTS=3629i
TOTAL NUMBER PR0CESSED-359C7
DISTANCE FROM ANTENNA 20000 METERS
40
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
T
S
30 •
20 •
10
0
0%
39
I
0%
34
I
0%
30
0%
27

0%
26
!
0*
n
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure CI5-8. Number of assignments for stations which can produce
specified power densities at 20,000 meters.

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAW
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY RANGE Cl.0-10.03 MW/CM2
400
N
M 300
B
0
F
A
S
S
200
N
I
y lea
0
IX
357
I
0X
104
i
0X
104
1
0*
60
¦
0*
14
0X
5
0X
14
0X
15
77A
2K
5K
10K
20K
100 200 500 IK
DISTANCE IN METERS
Figure B15-6. Number of assignments for stations which can	2
produce power densities between 1.0 and 10.0 mW/cm .

-------
600 T
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAMD
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED-35907
POWER DENSITY RANGE C.5-1.03 HW/CM2
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
500 -
400
300
200 -
100 ¦¦
0
100
0*
133
I
0*
31
0*
5G
200
M	W
500
J* 0z 0*
VJA 3 1
- i
IK
2K
0*
4-
5K
10K
20K
DISTANCE IN METERS
Figure B15-5. Number of assignments for stations which can
produce power densities between 0.5 and 1.0 mW/cm .

-------
COMPOSITE CEXCEPT EARTH STATIONS MAINBEAM5
TOTAL NUMBER OF ASSIGNMENTS=36291
TOTAL NUMBER PROCESSED=35907
POWER DENSITY RANGE C10.0-INF3 MW/CM2
200
N
U
M
0
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
100 ¦¦
0
0%
161
0%
144

0%
54
i
1_!
0*
35
1
0*
20
I
0*
27
1
0S
13
0X
11
M	^
100 200 500 IK 2K	5K
DISTANCE IN METERS
10K
20K
Figure B15-7. Number of assignments for stations which can
produce power densities greater than 10.0 mW/cm .

-------
TYPE C HISTOGRAMS
162

-------
300
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=G610
TOTAL NUMBER PROCESSED=GS10
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A
S
G
N
¥
S
200 -
100..
0
3*
217
I
0K
0X
0
0%
0
0%
0
0*
0
.05
.1
.5
1
10
.025
MINIMUM POWER DENSITY IN MW/P12
Figure Cl-2. Number of assignments for AM broadcast stations which can produce
specified power densities at 200 meters.

-------
AM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=6610
TOTAL NUMBER PROCESSED=661B
DISTANCE FROM ANTENNA 100 METERS
500
N 400
M
B
0 300
F
A
S
S
i
N
M
E
N
T
S
200 -
100
0
7%
454
I
0%
-2-
058
0
0*
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure Cl-1. Number of assignments for AM broadcast stations which can produce
specified power densities at 100 meters.

-------
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
DISTANCE FROM ANTENNA 200 METERS
20
N
U
M
B
E
R
0
F
A
S
s
1
c
N
M
T
S
10 •<
0
0S
IB
I
.025
0*
0
I
0*
0
0*
0
0%
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0X
0
t
10
Figure C2-2. Number of assignments for FM broadcast stations which can produce
specified power densities at 200 meters.

-------
4000 ¦ •
FM BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=9021
TOTAL NUMBER PROCESSED=9021
DISTANCE FROM ANTENNA 100 METERS
N
U
M 3000
B
E
R
2000
0
F
A
S
s
1
G
N
M
E
^ 1000
0
33*
3022
I
.025
20%
1B4G
I

m
19
0*
0
056
0
03
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C2-1. Number of assignments for FM broadcast stations which can produce
specified power densities at 100 meters.

-------
900 T
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED-4037
DISTANCE FROM ANTENNA 200 METERS
600 +
N
U 700
M
B
I
N
M
E
N
T
S
600 +
0
F 500
A
S
S
400 +
300 +
200 +
100 t
0
2%
0X
0
—i—
z%
0
—I—
JB25
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C3-2. Number of assignments for TV broadcast stations which can produce
specified power densities at 200 meters.

-------
2000 T
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED*4037
DISTANCE FROM ANTENNA 100 METERS
N
M
I
R
0
F
A
S
s
1
G
N
M
E
I
1000 --
0
26%
1137

.025
27%
1005

10%
393
656
223
I
0%
0
.05	.1	.5	1
MINIMUM POWER DENSITY1 IN MW/CM2
10
Figure C3-1. Number of assignments for TV broadcast stations which can produce
specified power densities at 100 meters.

-------
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSEDM037
DISTANCE FROM ANTENNA 1000 METERS
60 T
N
U
M
B
E
R
0
F
A
S
S
1
N
M
E
N
T
S
50
40 ••
30
20
10 •
0
.025
0ft
0
0«
0
0X
0
0ft
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0ft
0
—i—
10
Figure C3-4. Number of assignments for TV broadcast stations which can produce
specified power densities at 1,000 meters.

-------
400
TV BROADCAST
TOTAL NUMBER OF ASSIGNMENTS=4037
TOTAL NUMBER PROCESSED=4037
DISTANCE FROM ANTENNA 500 METERS
N
U
M
0
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
300
200 -
100 --
0
IX
54
1
0X
0
0%
0
0X
0
.025

.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C3-3. Number of assignments for TV broadcast stations which can produce
specified power densities at 500 meters.

-------
2000
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=i9676
TOTAL NUMBER PROCESSED-19676
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A 1000
N
M
0
.025
4%
762
I
2%
420
i
0X
84
V7fi
0X
e
0X
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C4-2. Number of assignments for broadcast stations which can produce
specified power densities at 200 meters.

-------
5000 T
N 4000
M
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PROCESSEO=19B7B
DISTANCE FROM ANTENNA 100 METERS
0
F
A
S
G
N
M
T
S
3000 -
2000
1000 • -
0
.025
2%
393
0
IX
223
0X
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C4-1. Number of assignments for broadcast stations which can produce
specified power densities at 100 meters.

-------
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=±9676
TOTAL NUMBER PROCESSED-19676
DISTANCE FROM ANTENNA 1000 METERS
N
U
M
0
F
A
S
N
M
60 r
50 •
40 •
30 ••
20 -
10
0
0*
54
I
0X
0
0*
0
0X
0
0X
0
0X
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C4-4. Number of assignments for broadcast stations which can produce
specified power densities at 1,000 meters.

-------
400
BROADCAST STATIONS COMPOSITE
TOTAL NUMBER OF ASSIGNMENTS=19676
TOTAL NUMBER PR0CESSED=19676
DISTANCE FROM ANTENNA 500 METERS
N
U
M 300
B
E
R
0
F
A
S
G
N
M
6
s
200 ¦
100 -
0
0%
54
1
0*
0
0X
0
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
0X
0
—i—
.025
10
Figure C4-3. Number of assignments for broadcast stations which can produce
specified power densities at 500 meters.

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A
5
1
g
M
6
s
50 r
40 +
30 +
20 +
10 +
0
10%
40
I
10*
1 45

5X
22
i
4%
21
I
4*
21
0%
0

.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C5-2. Number of assignments for civilian fixed beam radar stations which can
produce specified power densities at 200 meters.

-------
70 T
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=039
TOTAL NUMBER PR0CESSED=472
DISTANCE FROM ANTENNA 100 METERS
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
50 -
50
40 ¦¦
30 ¦¦
20 •
10
0
10X
46
1

4*
21
1
0%
0
—i—
10
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
Figure C5-1. Number of assignments for civilian fixed beam radar stations which can
produce specified power densities at 100 meters.

-------
0
F
30 T
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=839
TOTAL NUMBER PROCESSED-472
DISTANCE FROM ANTENNA 1000 METERS
N
U
M
B
E
R
20 ¦
G
N
M
6
s
10 -
0
z%
0%
0X
0K
058
q
0
0
0
0
.05
.1
.5
1
10
.025
MINIMUM POWER DENSITY IN MW/CM2
Figure C5-4. Number of assignments for civilian fixed beam radar stations
which can produce specified power densities at 1,000 meters.

-------
CIVILIAN FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=B39
TOTAL NUMBER PR0CESSED=472
DISTANCE FROM ANTENNA 500 METERS
30
N
U
M
B
E
R
0
F
A
S
S
1
G
N
M
E
N
T
S
20 ¦
10
0
5%
22
1
458
21
Z
i

4*
21
Z
I

0*
0
0%
0
0%
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C5-3. Number of assignments for civilian fixed beam radar stations which can
produce specified power densities at 500 meters.

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MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 100 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C7-1. Number of assignments for military fixed beam radar stations
which can produce specified power densities at 100 meters.

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CIVILIAN SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=594
TOTAL NUMBER PROCESSED=593
DISTANCE FROM ANTENNA 100 METERS
2 r
N
U
M
B
E
R
0
F
A
S
5
1
G
N
M
6
s
1
0
0%
0%
0%
0X
0*
0
0
0
0
0
.05
.1
.5
1
10
.025
MINIMUM POWER DENSITY IN MW/CM2
Figure C6-1. Number of assignments for civilian scanning radar stations which
can produce specified power densities at 100 meters.

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 500 METERS
30
N
U
M
B
0
F
A
S
S
1
G
N
M
E
N
T
S
20 -
10 ¦
0
7%
22
I
7%
20

5%
14

3*
8
3%
B
IX
2
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C7-3. Number of assignments for military fixed beam radar stations which
can produce specified power densities at 500 meters.

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 200 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C7-2. Number of assignments for military fixed beam radar stations
which can produce specified power densities at 200 meters.

-------
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 2000 METERS
N
U
M
B
20 T
?
A
S
I
S
M
10
0
4«
11
!
3*
10
I
IX
3
I
lft
2
IX
2

0ft
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure CIS. Number of assignments for military fixed beam radar stations which can
produce specified power densities at 2,000 meters.

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MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS«307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 1000 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C7-4. Number of assignments for military fixed beam radar stations
which can produce specified power densities at 1,000 meters.

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MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 10000 METERS
3
Figure C7-7. Number of assignments for military fixed beam radar stations which can
produce specified power densities at 10,000 meters.

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MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 5000 METERS
4
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
3
2
1 •
0
IX
1
1*
1 I

1*


1*

0X
0
0%
0
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C7-6. Number of assignments for military fixed beam radar stations which can
produce specified power densities at 5,000 meters.

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MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=105G
TOTAL NUMBER PROCESSED=1049
DISTANCE FROM ANTENNA 100 METERS
MINIMUM POWER DENSITY IN MW/CM2
Figure C8-1. Number of assignments for military scanning radar stations which can
produce specified power densities at 100 meters.

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0
F
3
MILITARY FIXED BEAM RADAR
TOTAL NUMBER OF ASSIGNMENTS=307
TOTAL NUMBER PROCESSED=300
DISTANCE FROM ANTENNA 20000 METERS
N
U
M
B
E
R
2
A
S
S
I
G
N
M
E
N
T
S
1 •
0
0*
0%
0%
0%
0%
0
0
0
0
0
.05
.1
.5
1
10
MINIMUM POWER DENSITY IN MW/CM2
Figure C7-8. Number of assignments for military fixed beam radar stations which can
produce specified power densities at 20,000 meters.

-------
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=iB5fl
TOTAL NUMBER PROCESSED=1049
DISTANCE FROM ANTENNA 500 METERS
N
U
M
B
E
R
0
F
A
S
G
N
M
6
I
3
8
7
6
5
4	+
3
2
1
0
0X
6

0%

0%

0X
0
0X
0
0X
0
—I—
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C8-3. Number of assignments for military scanning radar stations which can
produce specified power densities at 500 meters.

-------
MILITARY" SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1059
TOTAL NUMBER PR0CESSED=1849
DISTANCE FROM ANTENNA 200 METERS
40 r
N
U
M
B
E
R
0
F
A
S
5
1
c
N
M
6
s
30
20 -
10 ¦
0
2%
36

1%
23

1*
10
I
0%
0%
0

0%
0
—I—
10
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
Figure C8-2. Number of assignments for military scanning radar stations which can
produce specified power densities at 200 meters.

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EARTH STATIONS CMAINBEAMJ
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED»1509
DISTANCE FROM ANTENNA 100 METERS
1200 ¦
1100 ¦
N 1000
U
g 900
E'
R 800
0
F 700
A
| 600 -
jj 500
B
% 400
T
S 300
200 -
100
76*
1146
I
i72%
1081

62*
931
1
41*
613
I
1
i 1
30*
454
¦
I
13%
293
I
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C9-1. Number of assignments for earth stations which can produce specified mainbeam
power densities at 100 meters.

-------
7 T
MILITARY SCANNING RADAR
TOTAL NUMBER OF ASSIGNMENTS=1058
TOTAL NUMBER PR0CESSED=1849
DISTANCE FROM ANTENNA 1000 METERS
N
U
M
B
E
R
G •
5 -
0
F
4 ¦¦
A
S
S
I
S
g
N
T
S
3 ¦¦
2 ••
1 ¦
0
0K
0%
0X
Z%
m
0
0
0
0
0
.05
.1
.5
1
10
MINIMUM
POWER
DENSITY IN
MW/CM2

.025
Figure C8-4. Number of assignments for military scanning radar stations which can
produce specified power densities at 1,000 meters.

-------
EARTH STATIONS CMAINBEAMD
TOTAL NUMBER OF ASSIGNMENTS=i509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 500 METERS
N
U
M
B
E
R
0
F
A
1
G
8
1000 T
900
600
700
600
500
400
300
200
100
0
64%
969
I
61*
•915
I
.025
51*
772
I
33*
503
I
22%
333
I
IX
19
17771
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C9-3. Number of assignments for earth stations which can produce specified mainbeam
power densities at 500 meters.

-------
EARTH STATIONS CMAINBEAM)
TOTAL NUMBER OF ASSIGNMENTS=1509
TOTAL NUMBER PROCESSED=1509
DISTANCE FROM ANTENNA 200 METERS
N
U
M
B
E
R
0
F
A
S
s
1
G
N
M
E
N
T
S
1100 ¦
1000 -
300
000
700
G00
500 -
400 ¦
300 -
200
100
71*
1073

67*
1012
V.

I

5658
042
I
37*
560

29%
434

15*
226
m
.025
.05	.1	.5	1
MINIMUM POWER DENSITY IN MW/CM2
10
Figure C9-2. Number of assignments for earth stations which can produce specified mainbeam
power densities at 200 meters.

-------