For full format paper (including table, picture, graphic etc) Please open at BROADCAST ENGINEER’S HANDBOOK
A collection of useful reference data
for TV broadcasting engineers
Page 2
INDEX
Page
VHF Channel definitions ....................................................................................................................... 3
UHF Channel definitions ..................................................................................................................... 10
Basic standards for TV transmission ............................................................................................ 15
Minimum field strength for which protection may be sought
in planning a television service ....................................................................................................... 17
Boundaries of the television service area
in rural districts having a low population density .................................................................... 18
CO-Channel interference .................................................................................................................... 19
Frequency offset conditions ............................................................................................................. 21
Directivity of antennas in the reception of television broadcasting ................................. 24
Microwave radiation exposure - principal safety standards ................................................ 25
Coaxial cables ........................................................................................................................................ 27
Wave guides ............................................................................................................................................ 28
TV analogue microwave links ........................................................................................................... 29
VSWR vs. Return loss (dB) ................................................................................................................ 30
Half wave dipole vs. isotropic dipole ............................................................................................. 30
Relationship between dBm, W, dBmV, V ..................................................................................... 31
Cable size vs. maximum current ..................................................................................................... 32
Conversion factors ............................................................................................................................... 33
Useful formulae ..................................................................................................................................... 35
Useful RF calculation ........................................................................................................................... 37
The material contained in this handbook has been collected from a number of sources.
ABE Elettronica S.p.A. accepts no responsability for errors or omissions.
Page 3
VHF Channel definitions
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard B (7 Mhz), Australia
IF - 33.15 to 40.15 38.9 33.4
0 45 to 52 46.25 51.75
I 1 56 to 63 57.25 62.75
2 63 to 70 64.25 69.75
3 85 to 92 86.25 91.75
(II) 4 94 to 101 95.25 100.75
5 101 to 108 102.25 107.75
5A 137 to 144 138.25 143.25
6 174 to 181 175.25 180.75
7 181 to 188 182.25 187.75
III 8 188 to 195 189.25 194.75
9 195 to 202 196.25 201.75
10 208 to 215 209.25 214.75
11 215 to 222 216.25 221.75
Standard B (7 Mhz), Europe
IF - 33.15 to 40.15 38.9 33.4
E 2 47 to 54 48.25 53.75
I E 3 54 to 61 55.25 60.75
E 4 61 to 68 62.25 67.75
E 5 174 to 181 175.25 180.75
E 6 181 to 188 182.25 187.75
E 7 188 to 195 189.25 194.75
III E 8 195 to 202 196.25 201.75
E 9 202 to 209 203.25 208.75
E 10 209 to 216 210.25 215.75
E 11 216 to 223 217.25 222.75
E 12 223 to 230 224.25 229.75
Page 4
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard B (7 Mhz), Europe
Special cable TV channels (CATV)
IF - 33.15 to 40.15 38.9 33.4
S 2 113 to 123 digital sound
S 3 113 to 123 broadcasting
S 4 125 to 132 126.25 131.75
<III S 5 132 to 139 133.25 138.75
Su S 6 139 to 146 140.25 145.75
lower S 7 146 to 153 147.25 152.75
ATV S 8 153 to 160 154.25 159.75
bands S 9 160 to 167 161.25 166.75
S 10 167 to 174 168.25 173.75
S 11 230 to 237 231.25 236.75
S 12 237 to 244 238.25 243.75
S 13 244 to 251 245.25 250.75
S 14 251 to 258 252.25 257.75
>III S 15 258 to 265 259.25 264.75
So S 16 265 to 272 266.25 271.75
upper S 17 272 to 279 273.25 278.75
ATV S 18 279 to 286 280.25 285.25
bands S 19 286 to 293 287.25 292.75
S 20 293 to 300 294.25 299.75
Standard B (7 Mhz), Italy
IF - 33.15 to 40.15 38.9 33.4
I A 52.5 to 59.5 53.75 59.25
B 61 to 68 62.25 67.75
(II) C 81 to 88 82.25 87.75
D 174 to 181 175.25 180.75
E 182.5 to 189.5 183.75 189.25
F 191 to 198 192.25 197.75
(III) G 200 to 207 201.25 206.75
H 209 to 216 210.25 215.75
H1 216 to 223 217.25 222.75
H2 223 to 230 224.25 229.75
Page 5
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard B (7 Mhz), Marocco
IF - 33.15 to 40.15 38.9 33.4
M 4 162 to 169 163.25 168.75
M 5 170 to 177 171.25 176.75
M 6 178 to 185 179.25 184.75
III M 7 186 to 193 187.25 192.75
M 8 194 to 201 195.25 200.75
M 9 202 to 209 203.25 208.75
M 10 210 to 217 211.25 216.75
Standard B (7 Mhz), New Zealand
IF - 33.15 to 40.15 38.9 33.4
1 44 to 51 45.25 50.75
I 2 54 to 61 55.25 60.75
3 61 to 68 62.25 67.75
4 174 to 181 175.25 180.75
5 181 to 188 182.25 187.75
6 188 to 195 189.25 194.75
III 7 195 to 202 196.25 201.75
8 202 to 209 203.25 208.75
9 209 to 216 210.25 215.75
10 216 to 223 217.25 222.75
Standard D (8 Mhz), China (Peoples Rep.)
IF - 31.25 to 39.25 38.0 31.5
1 48.5 to 56.5 49.75 56.25
2 56.5 to 64.5 57.75 64.25
I 3 64.5 to 72.5 65.75 72.25
4 76.0 to 84.0 77.25 83.75
5 84.0 to 92.0 85.25 91.75
6 167 to 175 168.25 174.75
7 175 to 183 176.25 182.75
8 183 to 191 184.25 190.75
III 9 191 to 199 192.25 198.75
10 199 to 207 200.25 206.75
11 207 to 215 208.25 214.75
Page 6
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard D (8 Mhz), China (Peoples Rep.)
12 215 to 223 216.25 222.75
Standard D (8 Mhz), OIRT
IF* - 32.15 to 40.15 38.9 32.4
*UdSSR: 31.25 to 39.25/38.0/31.5 Mhz
R I 48.5 to 56.5 49.75 56.25
I R II 58 to 66 59.25 65.75
R III 76 to 84 77.25 83.75
(II) R IV 84 to 92 85.25 91.75
R V 92 to 100 93.25 99.75
R VI 174 to 182 175.25 181.75
R VII 182 to 190 183.25 189.75
R VIII 190 to 198 191.25 197.75
III R IX 198 to 206 199.25 205.75
R X 206 to 214 207.25 213.75
R XI 214 to 222 215.25 221.75
R XII 222 to 230 223.25 229.75
Standard I (8 Mhz), Ireland
IF - 32.15 to 40.15 38.9* 32.9*
*Gr.-Brit. Also 39.5 and 33.5 Mhz resp.
I A 44.5 to 52.5 45.75 51.75
I I B 52.5 to 60.5 53.75 59.75
I C 60.5 to 68.5 61.75 67.75
I D 174 to 182 175.25 181.25
I E 182 to 190 183.25 189.25
III I F 190 to 198 191.25 197.75
I G 198 to 206 199.25 205.25
I H 206 to 214 207.25 213.25
I J 214 to 222 215.25 221.25
Page 7
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard I (8 Mhz), South Africa
IF - 32.15 to 40.15 38.9 32.9
4 174 to 182 175.25 181.25
5 182 to 190 183.25 189.25
6 190 to 198 191.25 197.25
7 198 to 206 199.25 205.25
III 8 206 to 214 207.25 213.25
9 214 to 222 215.25 221.25
10 222 to 230 223.25 229.25
11 230 to 238 231.25 237.25
(12) 238 to 246 not defined
13 246 to 254 247.43 253.43
Standard K1 (8 Mhz)
French Overseas Post and Telecommunication Agency
IF - 31.45 to 39.45 32.7 39.2*
*Also 38.9 or 32.7 Mhz
4 174 to 182 175.25 181.75
5 182 to 190 183.25 189.75
III 6 190 to 198 191.25 197.75
7 198 to 206 199.25 205.75
8 206 to 214 207.25 213.75
9 214 to 222 215.25 221.75
Standard L (8 Mhz), France
IF - 31.45 to 39.45 32.7 39.2*
*Also 38.9 or 32.7 Mhz
A 41 to 49 47.75 41.25
I B 49 to 57 55.75 49.25
C 57 to 65 63.75 57.25
C 1 53.75 to 61.75 60.50 54.00
Page 8
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard L (8 Mhz), France
1 174.75 to 182.75 176.0 182.50
2 182.75 to 190.75 184.0 190.50
3 190.75 to 198.75 192.0 198.50
III 4 198.75 to 206.75 200.0 206.50
5 206.75 to 214.75 208.0 214.50
6 214.75 to 222.75 216.0 222.50
Standard M (6 Mhz), Japan
IF - 41.0 to 47.0 38.9 41.25
J 1 90 to 96 91.25 95.75
(II) J 2 96 to 102 97.25 101.75
J 3 102 to 108 103.25 107.75
J 4 170 to 176 171.25 175.75
J 5 176 to 182 177.25 181.75
J 6 182 to 188 183.25 187.75
J 7 188 to 194 189.25 193.75
Channel spacing 4 Mhz
III J 8 192 to 198 193.25 197.75
Channel spacing 4 Mhz
J 9 198 to 204 199.25 203.75
J 10 204 to 210 205.25 209.75
J 11 210 to 216 211.25 215.75
J 12 216 to 222 217.25 221.75
Standard M,N (6 Mhz), USA
IF - 41.0 to 47.0 45.75 41.25
A 02 54 to 60 55.25 59.75
A 03 60 to 66 61.25 65.75
I A 04 66 to 72 67.25 71.75
A 05 76 to 82 77.25 81.75
A 06 82 to 88 83.25 87.75
Page 9
BAND CHANNEL CHANNEL LIMITS
(MHZ) VISION CARRIER SOUND
CARRIER
Standard M,N (6 Mhz), USA
A 07 174 to 180 175.25 179.75
A 08 180 to 186 181.25 185.75
A 09 186 to 192 187.25 191.75
III A 10 192 to 198 193.25 197.75
A 11 198 to 204 199.25 203.75
A 12 204 to 210 205.25 209.75
A 13 210 to 216 211.25 215.75
Page 10
UHF Channel definitions
BAND CHANNEL CHANNEL
LIMITS MHZ
VISION
CARRIER
SOUND CARRIER
MHZ
EU Chi G,H I K,L
Standards G,H,I,K,L (CCIR standards;8 Mhz)
IF - - same of VHF for corrisponding country
21 13 470 to 478 471.25 476.25 477.25 477.75
22 14 478 to 486 479.25 484.75 485.25 485.75
23 15 486 to 494 487.25 492.75 493.25 493.75
24 16 494 to 502 495.25 500.75 501.25 501.75
25 17 502 to 510 503.25 508.75 509.25 509.75
26 18 510 to 518 511.25 516.75 517.25 517.75
27 19 518 to 526 519.25 524.75 525.25 525.75
28 20 526 to 534 527.25 532.75 533.25 533.75
IV 29 21 534 to 542 535.25 540.75 541.25 541.75
30 22 542 to 550 543.25 548.75 549.25 549.75
31 23 550 to 558 551.25 556.75 557.25 557.75
32 24 558 to 566 559.25 564.75 565.25 565.75
33 | 566 to 574 567.25 572.75 573.25 573.75
34 not 574 to 582 575.25 580.75 581.25 581.75
35 defi 582 to 590 583.25 588.75 589.25 589.75
36 ned 590 to 598 591.25 596.75 597.25 597.75
37 | 598 to 606 599.25 604.75 605.25 605.75
38 25 606 to 614 607.25 612.75 613.25 613.75
39 26 614 to 622 615.25 620.75 621.25 621.75
40 27 622 to 630 623.25 628.75 629.25 629.75
41 28 630 to 638 631.25 636.75 637.25 637.75
42 29 638 to 646 639.25 644.75 645.25 645.75
43 30 646 to 654 647.25 652.75 653.25 653.75
V 44 31 654 to 662 655.25 660.75 661.25 661.75
45 32 662 to 670 663.25 668.75 669.25 669.75
46 33 670 to 678 671.25 676.75 677.25 677.75
47 34 678 to 686 679.25 684.75 685.25 685.75
48 35 686 to 694 687.25 692.75 693.25 693.75
49 36 694 to 702 695.25 700.75 701.25 701.75
Page 11
BAND CHANNEL CHANNEL
LIMITS MHZ
VISION
CARRIER
SOUND CARRIER
MHZ
EU Chi G,H I K,L
Standards G,H,I,K,L (CCIR standards;8 Mhz)
50 37 702 to 710 703.25 708.75 709.25 709.75
51 38 710 to 718 711.25 716.75 717.25 717.75
52 39 718 to 726 719.25 724.75 725.25 725.75
53 40 726 to 734 727.25 732.75 733.25 733.75
54 41 734 to 742 735.25 740.75 741.25 741.75
55 42 742 to 750 743.25 748.75 749.25 749.75
56 43 750 to 758 751.25 756.75 757.25 757.75
57 44 758 to 766 759.25 764.75 765.25 765.75
58 45 766 to 774 767.25 772.75 773.25 773.75
59 46 774 to 782 775.25 780.75 781.25 781.75
60 47 782 to 790 783.25 788.75 789.25 789.75
61 48 790 to 798 791.25 796.75 797.25 797.75
V 62 49 798 to 806 799.25 804.75 805.25 805.25
63 50 806 to 814 807.25 812.75 813.25 813.25
64 51 814 to 822 815.25 820.75 821.25 821.25
65 52 822 to 830 823.25 828.75 829.25 829.25
66 53 830 to 838 831.25 836.75 837.25 837.25
67 54 838 to 846 839.25 844.75 845.25 845.25
68 55 846 to 854 847.25 852.75 853.25 853.75
69 56 854 to 862 855.25 860.75 861.25 861.75
| 57 862 to 870 863.25 869.75
not 58 870 to 878 871.25 877.75
defi 59 878 to 886 879.25 885.75
ned 60 886 to 894 887.25 893.75
| 61 894 to 902 895.25 901.75
| 62 902 to 910 903.25 909.75
EU = EUROPE
Chi = CHINA
Page 12
BAND CHANNEL CHANNEL LIMITS
MHZ
VISION
CARRIER SOUND CARRIER
USA Jap
Can
Standards M,N (6 Mhz), USA;Standards M (6 Mhz) Japan
IF - - same as VHF for corresponding country
14 13 470 to 476 471.25 475.75
15 14 476 to 482 477.25 481.75
IV other channels with 6 Mhz spacing
41 40 632 to 638 633.25 637.75
42 41 638 to 644 639.25 643.75
43 42 644 to 650 645.25 649.75
44 43 650 to 656 651.25 655.75
45 44 656 to 662 657.25 661.75
46 45 662 to 668 663.25 667.75
47 46 668 to 674 669.25 673.75
48 47 674 to 680 675.25 679.75
49 48 680 to 686 681.25 685.75
50 49 686 to 692 687.25 691.75
51 50 692 to 698 693.25 697.75
52 51 698 to 704 699.25 703.75
53 52 704 to 710 705.25 709.75
54 53 710 to 716 711.25 715.75
55 54 716 to 722 717.25 721.75
V 56 55 722 to 728 723.25 727.75
57 56 728 to 734 729.25 733.75
58 57 734 to 740 735.25 739.75
59 58 740 to 746 741.25 745.75
60 59 746 to 752 747.25 751.75
61 60 752 to 758 753.25 757.75
62 61 758 to 764 759.25 763.75
63 62 764 to 770 765.25 769.75
64 | 770 to 776 771.25 775.75
65 not 776 to 782 777.25 781.75
66 defi 782 to 790 783.25 787.75
67 ned 788 to 794 789.25 793.75
Page 13
BAND CHANNEL CHANNEL LIMITS
MHZ
VISION
CARRIER SOUND CARRIER
USA Jap
Can
Standards M,N (6 Mhz), USA;Standards M (6 Mhz) Japan
68 | 794 to 800 795.25 799.75
69 | 800 to 806 801.25 805.75
70 | 806 to 812 807.25 811.75
71 | 812 to 818 813.25 817.75
72 | 818 to 824 819.25 823.75
73 | 824 to 830 825.25 829.75
74 not 824 to 830 831.25 835.75
V 75 defi 830 to 836 837.25 841.75
76 ned 836 to 842 843.25 847.75
77 | 842 to 848 849.25 853.75
78 | 848 to 854 855.25 859.75
79 | 854 to 860 861.25 865.75
80 | 860 to 866 867.25 871.75
81 | 866 to 872 873.25 877.75
82 | 878 to 884 879.25 883.75
83 | 884 to 890 885.25 889.75
Standard B (7 Mhz), Australia
IF - 33.15 to 40.15 38.9 33.4
28 526 to 533 527.25 532.75
29 533 to 540 534.25 539.75
30 540 to 547 541.25 546.75
IV 31 547 to 554 548.25 553.75
32 554 to 561 555.25 560.75
33 561 to 568 562.25 567.75
34 568 to 575 569.25 574.75
35 575 to 582 576.25 581.75
36 582 to 589 583.25 588.75
37 589 to 596 590.25 595.75
38 596 to 603 597.25 602.75
39 603 to 610 604.25 609.75
40 610 to 617 611.25 616.75
Page 14
BAND CHANNEL CHANNEL LIMITS
MHZ
VISION
CARRIER SOUND CARRIER
Standard B (7 Mhz), Australia
41 617 to 624 618.25 623.75
42 624 to 631 625.25 630.75
43 631 to 638 632.25 637.75
44 638 to 645 639.25 644.75
45 645 to 652 646.25 651.75
46 652 to 659 653.25 658.75
47 659 to 666 660.25 665.75
48 666 to 673 667.25 672.75
49 673 to 680 674.25 679.75
50 680 to 687 681.25 686.75
51 687 to 694 688.25 693.75
52 694 to 701 695.25 700.75
53 701 to 708 702.25 707.75
54 708 to 715 709.25 714.75
55 715 to 722 716.25 721.75
56 722 to 729 723.25 728.75
57 729 to 736 730.25 735.75
58 736 to 743 737.25 742.75
59 743 to 750 744.25 749.75
60 750 to 757 751.25 756.75
61 757 to 764 758.25 763.75
62 764 to 801 765.25 770.75
63 771 to 779 772.25 777.75
64 778 to 786 779.25 784.75
65 785 to 793 786.25 791.75
66 792 to 799 793.25 798.75
67 799 to 806 800.25 805.75
68 806 to 813 807.25 812.75
69 813 to 820 814.25 819.75
USA = United States of America
Can = Canada
Jap = Japan
Page 15
Basic standards for TV transmission
* = group of territories represented by the French Overseas Post and Telecommunication Agency
2 = for colour transmission according to NTSC or SECAM
3 = 73% instead of nominal 75% applies for TV transmitters of high quality also in the sync range (burst, chrominance signal)
4 = 20:1 in the Federal Republic of Germany as of April 1976 for all trasmission of the three programs
5 = 6.7:1 and 2.9:1 in Japan
6 = for dual-sound or stereo sound in the Federal Republic of Germany
STANDARD B/G D/K H
CCIR OIRT BELGIUM
Frequency VHF/UHF VHF/UHF UHF
Number of lines for frame 625 625 625
Field frequency Hz 50 50 50
Line frequency Hz 15625 15625 15625
Duration of line sync pulse μs 4.7 4.7 4.7
Duration of line blanking pulse μs 12 12 12
Front porch μs 1.5 1.5 1.5
Field blanking interval Lines 25 25 25
Standard color system PAL/SECAM SECAM PAL/SECAM
Chrominance subcarrier freq. Hz
PAL Hz 4433618.75±5 4433618.75±5
SECAM/NTSC Hz
fOR=4406250±2000
fOB=4250000±2000
fOR=4406250±2000
fOB=4250000±2000
fOR=4406250±2000
fOB=4250000±2000
kHz (fO=4286±20) (fO=4286±20) (fO=4286±20)
fOR=282fH fOB=272fH fOR=282fH fOB=272fH fOR=282fH fOB=272fH
Video bandwidth Mhz 5 6 5
RF channel width Mhz 7(B) / 8(G) 8 8
Vision-sound carrier spacing Mhz +5.5 +5.746 +6.5 +5.5
Width of vestigial sideband Mhz 0.75 0.75 1.25
Spacing of vision carrier from
nearest edge of channel
Mhz +1.25 +1.25 +1.25
RF sync level % 100 100 100
RF blanking level % 733 75 75
RF white level (residual carrier) % 10 12.5 10
Type of vision modulation C3F neg. C3F neg. C3F neg.
Type of sound modulation F3E F3EH6 F3E F3E
Frequency deviation ±50 ±50 ±50
Preemphasis μs 50 50 50
Vision/Sound power ratio 10:1 to 20:14 20:1:0.26 10:1 to5:1 5:1 to10:1
Page 16
I K1 OR K L M N
UK FOPTA* FRANCE FCC SOUTH AMERICA
VHF/UHF VHF/UHF VHF/UHF VHF/UHF VHF/UHF
625 625 625 525 625
50 50 50 60 50
15625 15625 15625 15750 15625
4.7 4.7 4.7 5 (4.7)2 5
12 12 12 10.8 (11)2 10.9
1.5 1.5 1.5 1.9 (1.75)2 1.9
25 25 25 19 to 21 19 to 25
PAL SECAM SECAM PAL/NTSC PAL
__________±_ 3575611.49±10 3582056.25±5
fOR=4406250±2000
fOB=4250000±2000
fOR=4406250±2000
fOB=4250000±2000
3579545±10
(fO=4286±20) (fO=4286±20)
fOR=282fH fOB=272fH fOR=282fH fOB=272fH
5.5 6 6 4.2 4.2
8 8 8 6 6
+6 +6.5 ±6.5 +4.5 +4.5
1.25 1.25 1.25 0.75 0.75
+1.25 +1.25 +1.25 +1.25 +1.25
100 100 <6 100 100
76 75 30 75 75
20 10 100 (110)2 10 10
C3F neg. C3F neg. C3F pos. C3F neg. C3F neg.
F3E F3E A3E F3E F3E
±__ ±50 - ±25 ±25
50 50 - 75 75
5:1 10:1 10:1 10:1 to 5:15 10:1 to 5:1
Page 17
Minimum field strength for which protection may be sought in planning
a television service
(Ref.: CCIR Rec. 417-3)
G When planning a television service in bands I, III, IV, V, the median field strength for which protection
against interference is planned should never be lower than:
(1) The values shown for band IV and V should be increased by 2 dB for the 625-line (OIRT) system
These values refers to the field strength at a height of 10m above ground level;
G The percentage of time for which the protection may be sought should lie between 90% and 99%
Note1. In arriving at the figure shown above, it has been assumed that, in the absence of interference
from other television transmissions and man-made noise, the minimum field strength at the receiving
antenna that will give a satisfactory grade of picture, taking into consideration receiver noise, cosmic
noise, antenna gain and feeder loss, are: +47dB(mV/m) in Band I, +53 dB(mV/m) in Band III, +62 dB(mV/
m) in Band IV and +67 dB(mV/m) in Band V
Note 2. Further information concerning the planning of television service for sparsely populated regions
is contained in CCIR report 409.
Note 3. In a practical plan, because of interference from other television transmissions, the field
strengths that can be protected will generally be higher than those quoted above, and the exact values
to be used in the boundary areas between any two countries should be agreed between the
administrations concerned.
BAND I III IV V
G%__mV/m) +48 +55 +65(1) +70(1)
Page 18
Boundaries of the television service area in rural districts having a low
population density
(Ref.: CCIR Rep. 409 - 4)
Where television services are to be provided for a sparsely populated region, in which better receivers
and antenna installation are likely to be employed than those considered in CCIR Rec. 417,
administrations may find it desirable to establish the appropriate median field strength for which
protection against interference is planned as low as shown below.
These values refer to the field strength at a height of 10 m above ground level.
In the absence of interference other than noise, field strength of the order of 40 dB(mV/m) in Band I, 43
dB(mV/m) in Band III, 52 dB(mV/m) in Band IV, 58 dB(mV/m) in Band V can give satisfactory pictures;
however, it is generally observed that the public begin to lose interest in installing television reception
equipment when the field strength falls much below these levels.
The values given in this Report have been obtained from field-strength investigations at the edge of the
coverage area and picture quality assessments for Bands I and III in rural districts of Australia [CCIR,
1963-66], India [CCIR, 1974-78] and Italy, for Bands IV, and V at both rural and urban location in Italy
and the United Kingdom [CCIR, 1982-86]. It may be noted that in Bands IV and V where man-made
noise is not generally a problem, the field strength values quoted for rural areas, may also be applied
in urban areas.
BAND I III IV V
G%_mV/m) +46 +49 +58 +64
Page 19
CO-Channel interference
(Ref.: CCIR Rec. 655)
The protection ratios between two television signals apply only for interference due to the modulated
vision carrier of the unwanted signal. Additional protection may be necessary if the wanted sound
carrier is affected, or if the unwanted sound carrier lies within the wanted vision channel (e.g. the
unwanted sound carrier of the system G lies within the vision channel of system K). For all protection
ratio figures in this section, the following correction have to be made:
When the wanted signal is modulated negatively and the unwanted signal is modulated positively (L/
SECAM), the values should be increased by 2 dB.
When the wanted signal is modulated positively and the unwanted signal is modulated negatively, the
values shuold be reduced by 2 dB.
Correction is not necessary if the wanted and unwanted signals have the same modulation polarity.
G Carriers separated by less then 1000 Hz, non-controlled systems having the same or different line
standard:
u Protection ratio: 45 dB, tropospheric interference
G Carriers separated by parts of the line frequency, systems having the same line-standard, nonprecision
offset:
Protection ratio, tropospheric interference carrier separation up to about ±36/12 fline (about ±50kHz)
where fline=line frequency
G 625-line system, carriers separated by multiples of a twelfth of the line frequency up to about ±36/
12 fline (about ±50 kHz):
OFFSET OF LINE
FREQUENCY 1/2,3/2,5/2,..... 1/3,2/3,4/3,.....
625-line system (dB) 27 30
525-line system (dB) 25 28
Page 20
These protection ratio values do not necessarily apply for greater carrier separations.
Protection ratio between 625-line systems:
Limit of perceptibility - only for information. (Value in the first column is only valid for the 0/12 case. All
other values between 1/12 and 12/12 are the same by addition or subtraction of integral multiples of 12/
12 up to ±36/12).
OFFSET
(MULTIPLES OF 1/12 LINE
FREQUENCY)
0 1 2 3 4 5 6 7 8 9 10 11 12
Non precision
offset
Transmitter
stability
± 500 Hz
Tropospheric
interference (dB)
45 44 40 34 30 28 27 28 30 34 40 44 45
Continuous
interference (dB)
52 51 48 44 40 36 33 36 40 44 48 51 52
Limit of
perceptibility (dB)
61 60 57 54 50 45 42 45 50 54 57 60 61
Precision offset
Transmitter
stability
± 1 Hz
Tropospheric
interference (dB)
32 34 30 26 22 22 24 22 22 26 30 34 38
Continuous
interference (dB)
36 38 34 30 27 27 30 27 27 30 34 38 42
Limit of
perceptibility (dB)
42 44 40 36 36 39 42 39 36 36 40 44 48
Page 21
Frequency offset conditions
The required protection ratio varies considerably depending on the frequency relationship between the
wanted and the unwanted carriers and their frequency tolerance. The greatest protection is required
when the frequency of one or both carriers is non-controlled.
Less interference is possible and therefore lower protection ratios are required for non precision offset
(line frequency offset). Non-precision offset takes advantage of the line frequency structure of the video
signal and, in particular, it is advantageous to offset the carriers by multiples of one-half or one-third of
the line frequency. The long-term stability of these favourable protection ratios can only be guaranteed,
however, if the frequencies of the wanted and unwanted signals are kept within ±500Hz.
Precision offset takes further advantage of the field frequency structure of the video spectrum. The least
protection is required when both carriers are precision offset controlled within a tolerance of ±1 Hz for
the wanted and unwanted carriers. In the following figure is shown the main characteristic of offset
operation which plots in schematic form the protection ratio curves between 0/12 fline and 12/12 fline.
These curves are cyclic and their extensions to the left and the right are symbolized by broken lines.
These various conditions illustrated are similar within the luminance range up to about ±3 Mhz.
The upper and lower curves indicate, respectively, the protection ratio obtained with non-precision and
precision offset. More precisely, these two curves trace the envelope of a series of fluctuations in the
protection ratio which swings between the two curves at field frequency as represented by the thin line.
Page 22
CO-Channel protection ratio curves in the vicinity of 0/12, 4/12 and 6/12
line frequency (625-line system)
The following figure gives examples of protection ratio curves for the three most important offset
position (0/12,4/12 and 6/12 fline). The curves in each graph relate to the tropospheric interference,
continuous interference and the limit of perceptibility.
The white and black points indicate the positions for non precision and precision offset respectively .
The reference impairment points for tropospheric and continuous interference are also indicated in the
figure.
When operating TV transmitter networks with synchronized as well as phase locked carriers, the
protection ratio values are slightly reduced.
Page 23
Page 24
Directivity of antennas in the reception of television broadcasting
(Ref.: CCIR Rec. 419-1)
Characteristics of directivity of the receiving antennas that can be used for planning terrestrial television
services in broadcasting Bands I, III, IV and V .
G It is considered that the discrimination shown will be available at the majority of antenna location in
built-up areas. At clear sites in open country, slightly higher values will be obtained.
G The curves shown above are valid for signals of vertical or horizontal polarization, when both the
wanted and the unwanted signals have the same polarization.
Page 25
Microwave radiation exposure - principal safety standards
Frequency range:
G USAS C95.1 - 10 Mhz - 100 Ghz
G Military - all microwave frequencies - range not specified
G USSR - 300 Mhz to 30 Ghz
G Czech - 300 Mhz to 300 Ghz
Definition of Power Density:
Power Densities referred to in standards is that average density measured in accessible regions
(USASI, or military) or at actual exposure sites (USSR and Czech) in the absence of subject.
Averaging time:
USAS C95.1 - 0.1 hour or 6 minutes
AF and ARMY - 0.01 hour or 36 seconds
Navy - 3 seconds
USSR - not specified
Czech - not specified, but the standard implies that an average density is calculated from an integrated
dose. For example, for occupational situations the maximum permissible exposure is given by:
averaged over 8 hours where P is power density and T is time in hour. The total exposure dose over
five consecutive working days is summed and divided by 5 to obtain an average exposure dose for 8
hours.
Dependence on Area of Exposure:
No distinctions are generally made between partial and whole body exposure.
Modification for Pulse or Other Modulation:
None except for reduction of exposure level by a factor of 2.5 in Czech standards.
3G7 < 200 microwatts / cm2 - hours
0
8ò
Page 26
Restriction on Peak Power:
None.
Allowance for Environment:
None except for proposal by Mumford to reduce the radiation exposure guide from 10 mw/cm2
according to the formula Po(mw/cm2) = 10 - (THI - 70) for values of the temperature-humidity index
(THI) in the range of 70 to 79 with Po = 1 mw/cm2 for THI above 79.
Instrumentation:
Generally not well specified but far-field type probes such as small horns or open waveguides are
specified with effective apertures Ae = l2 / 4pG where G is the power gain. Response times are not well
specified but are implied to be much greater than pulse durations and much smaller than duration of
exposure, generally of the order of seconds. Some use of true dosimetry, integrated absorbed energy
is made in USSR and Czechoslovakia.
Under USSR standard exposure near 1 mW/cm2 is permitted only with use of protective goggles for the
eyes.
Page 27
Coaxial cables
CABLE
TYPE
IMPEDANCE
W DIELECTRIC VELOCITY
FACTOR
FREQUENCY [MHZ]
MAXIMUM POWER [KW] /
ATTENUATION [DB/100 M]
50 100
Kw dB Kw dB
RG 58 50 Compact Polythene 0.67 0.42 10.8 0.3 16.1
RG 59 75 Compact Polythene 0.66 0.75 8.0 0.50 11.2
RG 213 50 Compact Polythene 0.66 2.7 4.27 1.7 6.23
RG 8 52 Compact Polythene 0.66 2.7 4.27 1.7 6.23
RG 11 75 Compact Polythene 0.66 1.7 4.80 1.03 7.0
1/4 Inch 50 Expanded Polythene (FOAM) 0.84 0.985 4.17 0.690 5.94
1/2 Inch 50 Expanded Polythene (FOAM) 0.81 2.91 2.40 2.03 3.44
7/8 Inch 50 Expanded Polythene (FOAM) 0.89 7.74 0.843 5.38 1.21
1+5/8 Inch 50 Expanded Polythene (FOAM) 0.88 19.3 0.512 13.4 0.738
1/2 Inch 50 Air Dielectric 0.914 2.97 1.90 2.10 2.72
5/8 Inch 50 Air Dielectric 0.92 6.00 1.12 4.21 1.60
7/8 Inch 50 Air Dielectric 0.90 9.20 0.853 6.40 1.21
1+5/8 Inch 50 Air Dielectric 0.921 20.7 0.476 14.4 0.679
3 Inch 50 Air Dielectric 0.933 54.0 0.322 29.1 0.448
4 Inch 50 Air Dielectric 0.92 82.0 0.256 56.0 0.371
5 Inch 50 Air Dielectric 0.931 107 0.177 73.0 0.259
Page 28
Wave guides
FREQUENCY [MHZ]
Maximum power [Kw] / Attenuation [dB/100 m]
200 500 800 1000 2000 3000 8000
Kw dB Kw dB Kw dB Kw dB Kw dB Kw dB Kw dB
0.2 24.3 0.18 39.6 0.14 39.8 0.125 55.0 0.08 75.0 0.62 111.5 - -
0.35 16.1 0.23 27.0 0.17 37.0 0.15 43.0 0.09 68.0 0.07 85.0 - -
1.1 8.86 0.65 17.0 0.48 23.0 0.40 26.0 0.30 43.0 0.19 57.0 - -
1.1 8.86 0.65 17.0 0.48 23.0 0.40 26.0 0.30 43.0 0.19 57.0 - -
0.81 10.03 0.48 17.0 0.36 25.0 0.30 29.0 0.19 46.0 0.15 60.0 - -
0.482 8.46 0.298 13.7 0.231 17.5 0.205 19.7 0.14 28.6 0.111 35.8 0.062 62.7
1.42 4.92 0.867 8.06 0.669 10.4 0.59 11.7 0.4 17.4 0.318 22.1 0.166 42.0
3.72 1.76 2.25 2.90 1.73 3.78 1.52 4.30 1.01 6.46 0.785 8.31 - -
9.22 1.08 5.53 1.79 4.21 2.36 3.69 2.69 2.42 4.10 - - - -
1.48 3.90 0.924 6.13 0.720 7.77 0.640 8.69 0.44 12.6 0.338 16.2 0.175 32.2
2.94 2.29 1.82 3.71 1.41 4.76 1.25 5.37 0.858 7.86 0.682 9.89 - -
4.40 1.77 2.69 2.85 2.09 3.68 1.85 4.17 1.30 6.07 1.0 7.90 - -
10.0 0.951 6.21 1.57 4.82 2.03 4.30 2.30 2.90 3.44 - - - -
25.0 0.682 14.6 1.2 9.24 1.60 9.30 1.84 - - - - - -
38.7 0.545 22.6 0.943 17.1 1.24 15.0 1.41 - - - - - -
51.0 0.377 30.7 0.626 23.0 0.820 - - - - - - - -
GUIDE TYPE
TE11MODE
CUTOFF
[GHZ]
MAXIMUM
FREQ. RANGE
[GHZ]
ATTENUATION
[DB/100 M]
MAX POWER
[W]
VELOCITY
FACTOR
EW 127 A 7.67 10.0 - 13.25 11.83 1.24 0.78
EW 132 9.22 11.0 - 15.35 15.84 0.85 0.78
Page 29
TV analogue microwave links
SYSTEM STANDARD
IF FREQUENCY: 70 Mhz
MODULATION TYPE: F.M.
NOMINAL FREQUENCY DEVIATION: 8 Mhz p.p.
(REC. 276-2)
PREEMPHASIS / DEEMPHASIS: 525 Lines Standard or
625 Lines Standard
(REC. 405 - 1)
STANDARD AUDIO CARRIERS
FREQUENCY: 7.500 Mhz (1°)
8.590 Mhz
7.020 Mhz
8.65Mhz
(REP. 289-4)
AUDIO SUBCARRIER MODULATION
TYPE: F.M.
STANDARD NOMINAL MAXIMUM AUDIO
SUBCARRIER DEVIATION
(with audio signal): ±_____.K]_S_
STANDARD AUDIO SUBCARRIER
PREEMPHASIS: __m6
Page 30
VSWR vs. Return loss (dB)
Half wave dipole vs. isotropic dipole
Half wave dipole gain (with reference to isotropic radiatior) @ 2.2 dB
Units:
Antenna gain (with reference to isotropic radiator): dBi
Antenna gain (with reference to half wave dipole): dBd
Generally: dBd = dBi - 2.2
VSWR RETURN LOSS (DB)
1.00 ¥
1.05 32.3
1.10 26.4
1.15 23.1
1.20 20.8
1.22 20.1
1.25 19.1
1.30 17.7
1.40 15.6
1.50 14.0
1.70 11.7
1.92 10.0
2.00 9.5
3.00 6.0
6.00 2.9
10.00 1.7
Page 31
5HODWLRQVKLS_EHWZHHQ_G%P__:__G%m9__9_
These values refers to 50 W Impedance. (For 75 W voltage values must be increased by 20%).
dBm POWER '%m9 VOLTAGE
-100 0.1 pW 7 2.2 mV
-90 1 pW 17 7 mV
-80 10 pW 27 22 mV
-70 100 pW 37 70 mV
-60 1 nW 47 220 mV
-50 10 nW 57 700 mV
-47 20 nW 60 1 mV
-40 100 nW 67 2.2 mV
-30 1 mV 77 7 mV
-20 10 mV 87 22 mV
-10 100 mV 97 70 mV
0 1 mW 107 220 mV
10 10 mW 117 700 mV
20 100 mW 127 2.2 V
30 1 W 137 7 V
40 10 W 147 22 V
50 100 W 157 70 V
60 1 kW 167 220 V
70 10 kW 177 700 V
80 100 kW 187 2.2 kV
90 1 MW 197 7 kV
Page 32
Cable size vs. maximum current
Maximum current carrying capacity for copper cable insulated with proper rubber and textile.This
capacities for cable placed in free air with an ambient temperature of 35 °.
These values are for cables in free air (not bunded) at any ambient.
NOMINAL
CROSS
SECTION
AREA
PLACED IN FREE AIR
1-pole cable 2-pole cable 3-pole cable N°of conductors Diameter
(mm)
mm2 Amperes Amperes Amperes
0.5 3 3 3 1 0.8
0.75 5 5 5 1 1
1 7 7 7 1 1.15
1.5 10 10 10 1 1.4
2.5 16 16 16 1 1.8
4 22 22 22 1 2.25
6 31 30 30 1 2.8
10 47 45 40 7 1.35
16 66 61 51 7 1.7
25 88 83 68 7 2.15
35 108 95 84 7 2.5
50 135 128 105 19 1.8
75 176 167 135 19 2.25
100 213 202 165 19 2.6
120 240 227 186 37 2
150 280 263 217 37 2.25
180 325 300 245 37 2.5
200 375 320 260 37 2.6
Page 33
Conversion factors
LENGTH:
(1)Terr. Mile = Terrestrial Mile; (2)Naut. Mile = Nautical Mile;
1 micron = 1E-3 millimetres;
1 angstrom = 1E-7 millimetres
PRESSURE
(1)Atm. = Atmosphere; (2)Pa. = Pascal
MASS
UNITS METER MILS INCH FEET YARD TERR.
MILE (1)
NAUT.
MILE(2)
METER 1 39370 39.37 3.281 1.094 0.000621 0.00054
MILS 2.540E-5 1 0.001 8.333E-5 2.778E-5 - -
INCH 0.02540 1000 1 0.083 0.0278 - -
FEET 0.3048 12000 12 1 0.333 - -
YARD 0.914 35997 36 3 1 - -
TERR.
MILE(1) 1609 - - 5279 1760 1 0.868
NAUT.
MILE(2) 1853 - - 6080 2027 1.151 1
UNITS ATM.(1) MMH20 MMHG PA.(2) BAR KG/CM2
ATM.(1) 1 10332 760 101325 1.01327 1.03333
MMH20 9.68E-5 1 0.07355 9.81 9.81E-5 1.0003E-4
MMHG 1.316E-3 13.597 1 133.34 1.333E-3 1.359E-3
PA.(2) 9.87E-6 0.102 7.5E-3 1 1.0001E-5 1.02E-5
BAR 0.9869 10196.69 750.04 99998.02 1 1.02
KG/CM2 0.9677 9998.74 735.486 98059.61 0.980 1
UNITS KILOGRAM POUND OUNCE DYNES
KILOGRAM 1 2.205 35.27 980665
POUND 0.4535 1 16 444746
OUNCE 0.02835 0.0625 1 27804.5
DYNES 1.02E-6 2.248E-6 36E-6 1
Page 34
TEMPERATURE
(1) °C = Celsius; (2) °F = Fahreneit; K = Kelvin; °R = Rankine
ENERGY
POWER
UNITS °C(1) °F(2) K(3) °R(4)
°C(1) - (5*°F)/9-17.78 K-273.15 (5*°R/9)-273.17
°F(2) (9*°C/5)+32 - (9*°K/5)-459.67 °R-459.67
K(3) °C+273.15 (5*°F/9)+255.37 - (5*°R)/9
°R(4) (9*°C/5)+491.67 °F+459.67 (9 °R)/5 -
UNITS BTU CALORIE,GRAM JOULE ERG
BTU 1 252 1054.8 1.055E10
CALORIE,GRAM 3.9685E-3 1 4.1857 41865079.36
JOULE 9.48E-4 0.2389 1 1E7
ERG 9.48E-11 0.2389E-7 1E-7 1
UNITS WATT BTU/HR HP KG-CAL/MIN
WATT 1 3.412 1.341E-3 0.01433
BTU/HR 0.2931 1 3.93E-4 4.2E-3
HP 745.712 2544.22 1 10.68
KG-CAL/MIN 69.78 238.1 0.0936 1
Page 35
Useful formulae
Electrical formulae
Electrical power in KW:
G DC power [KW]:
G AC power (single phase) [KW]:
G AC power (three-phase) [KW]:
where:
Volt: linked voltage
Ampere: single phase current or balanced mean of the 3 cables current
All with balanced load
j = power factor
General information
Medium radius of earth = 6371.03 Km
Equatorial radius of earth = 6376.8 Km
Polar radius of earth = 6355.41
Resistivity for some common metals:
Silver 0.0164 W*mm2/m
Copper 0.0178 W*mm2/m
Gold 0.0223 W*mm2/m
Brass 0.077 W*mm2/m
173
1000
. ´ cos( )
´
´
YROW DPSHUH
j
YROW ´ DPSHUH
´
1000
cos(j)
YROW ´ DPSHUH
1000
Page 36
RF formulae
G Wavelength in free space:
G Reflection coefficient vs. impedance:
u Z = Load impedance (W)
u Zo = Characteristic impedance of the line (W)
G Voltage standing wave ratio:
where = magnitude of reflection coefficient
G Reflection coefficient:
G Return loss (dB) : -K (dB) = -20*LOG (K) VSWR (dB) = 20*LOG (VSWR)
G Ratio of power transmitted: 1-K2
G Loss due to VSWR : -(1- K2) (dB)=10*LOG (1- K2)
G
96:5 =
+
-
1
1
G
G
G =
-
+
= =R
= =R
l ( )
( ) ( )
PHWHU
(
IUHT +] IUHT 0K]
= =
3 8 300
.
96:5
96:5
=
-
+
1
1
Page 37
Useful RF calculation
Free space attenuation or path loss between two points:
The calculation is made assuming ideal conditions, ie:
No reflection from terrain,etc
No atmosferic (climatic) attenuation
No obstruction within the first Fresnel ellipsoid
Use of isotropic antennas at either end of the path
[A]: Frequency - Frequency for calculation expressed in MHz
[B]: Distance - Distance between transmitting and receiving antennas, in Km
Free Space Attenuation (path loss) [dB]= 20 x LOG (A) + 20 x LOG (B) + 32.5
6LJQDO_Þ_)LHOG_6WUHQJWK_
Signal field strength at the location of the receiving antenna, given the received signal level measured
at the output connector of this antenna, across 50 Ohms.
[A]: Frequency- the frequency of the calculation, expressed in MHz
[B]: Rx antenna gain- the gain of the complete receiving antenna, expressed in dBd (which is the gain
in dB referred to a half wavelength dipole) in the actual direction (horizontally and vertically) in which
the transmitting antenna is situated.
[C]: Received signal(dBuV)- the received signal voltage expressed in dB relative to 1uV (microvolt)
measured at the output connector of the receiving antenna across a resistive impedance of 50 Ohms
Field strength [dBuV / m] = 20 10
2
300
´ 20 ´
´ ´ æ
è ç
öø ÷
é
ë êê
ù
û úú
- æ
è ç
öø ÷
/RJ
$ & % p
Page 38
Parabolic Antenna Gain
Calculation of parabolic antenna gain, with the prime focus feed, with respect to an isotropic radiator
(dBi).
[A]: Diameter - the diameter of the antenna, measured rim-to-rim directly across the parabolic reflector,
expressed in metres
[B]: Frequency - the frequency for the calculation, expressed in GHz
[C]: Efficiency factor - efficiency factor for the illumination of the antenna. This takes into account the
fact that the radiation from the feed does not illuminate the reflector uniformly. If the efficiency is not
known, 0.55 may be assumed
Fresnel Zone Radius
Calculates the radius (minus axis/2 in metres) of the First Fresnel Ellipsoid at any point on the path.
This is the zone which must be free from any obstruction in order to prevent attenuation, in excess of
the free space value, caused by reflection from obstructions.
[A]: Path length - the direct distance between the transmitting and receiving antennas, measured in a
straight line, expressed in Km
[B]: Distance from calculation point to path end - it is the distance from calculation point to the path end,
measured horizontally in a straight line, expressed in Km.
[C]: Frequency - the frequency for the calculation, expressed in GHz
Parabolic antenna gain [dBi] = 10 4
2
03
2
2
2 ´ ´´ ´
æè ç
öø ÷
æè ç
öø ÷
é
ë
êêêê
ù
û
úúúú
ì
í
ïï
î
ïï
ü
ý
ïï
þ
ïï
/RJ &
$
%
p
.
Page 39
1st Fresnel zone radius over obstacle:
( )
[m] =
03
1000 1000
1
1000
2
.
&
% $ %
$
æè ç
öø ÷
´ ´ ´ - ´ ´
´
æè ç
öø ÷
Page 40
NOTES
Page 41
NOTES
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