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JANUARY 1994
ADVANCE INFORMATION
D.S. 3802 1.3
SL5067
MULTI - STANDARD VIDEO MODULATOR
The SL5067 is a video up converter, capable of operating at frequencies up to 900MHz. It is compatible with both PAL and NTSC, accepting baseband video and sound inputs and modulating up to any desired VHF or UHF channel. Modulated UHF outputs consist of open collectors driving external 75W load resistors for line matching requirements. Prescaler outputs are also provided enabling the use of a synthesiser to control oscillator frequency. The SL5067 operates from a 5V supply.
MOD OUTPUT 2 MOD OUTPUT 1 MOD INDEX VIDEO INPUT AGC HOLD GND
1 2 3 4
20 19 18 17
GND VCC FM/AM SELECT AUDIO INPUT SOUND OSC 1 SOUND OSC 2 GND LO INPUT 2 LO OUTPUT 2 LO VCC
SL5067
5 6 7 8 9 10
16 15 14 13 12 11
FEATURES 5V Operation Symmetrical RF Oscillator Operating to 900MHz Symmetrical RF drive to a frequency synthesiser Video Signal Input Clamp Video Peak White Level Detection and Automatic Gain Control Control of Video Modulation Index Direct Drive into 75W, via Symmetrical open Collector Outputs ESD Protection Picture Carrier to Sound Carrier Ratio Adjustment Low External Component Count ESD Precautions must be observed
SL5067
J J J J J J J J J J
PRESCALER OUTPUT 1 PRESCALER OUTPUT 2 LO INPUT 1 LO OUTPUT 1
DP20
MOD OUTPUT 2 MOD OUTPUT 1 MOD INDEX VIDEO INPUT AGC HOLD GND PRESCALER OUTPUT 1 PRESCALER OUTPUT 2 LO INPUT 1 LO OUTPUT 1 1 2 3 4 5 6 7 8 9 10 20 19 18 17 16 15 14 13 12 11 GND VCC FM/AM SELECT AUDIO INPUT SOUND OSC 1 SOUND OSC 2 GND LO INPUT 2 LO OUTPUT 2 LO VCC
[
[
APPLICATIONS Video Recorders Cable Systems Video Cameras Personal Computers Video Security Systems In Home Rebroadcast System (LPTV)
J J J J J J
MP20
Fig. 1 Pin connections - top view
ORDERING INFORMATION
SL5067 /KG/DPAS SL5067 KG/MPES SL5067/KG/MPEF (Tape and Reel)
SL5067
PRESCALER OUTPUTS 7 UHF OSC 8 UHF MIXER 1 MODULATED OUTPUTS 2
UHF TANK
9 10 12 13
VIDEO VIDEO 4 INPUTS 75W CLAMP AGC MIXER DRIVER AUDIO FM/AM SELECT
AUDIO OSC 15 16 SND TANK
17
AUDIO INPUT
3 MOD INDEX
18 PC/SC ADJUST
Fig. 2 SL5067 block diagram
ELECTRICAL CHARACTERISTICS
Tamb= -10C to VCC=)4.5V to These characteristics are guaranteed over the following conditions (unless otherwise stated). They apply within the specified ambient temperature and supply voltage ranges. Value Characteristics Supply Voltage Supply Current LO Prescaler Output Level LO Prescaler Output Impedance LO drift with temp from switch on LO variation with supply RF carrier output level Video Input Video mod index Video Signal/Noise Ratio Sound Subcarrier temperature drift from switch on Sound drift with supply Audio Input Impedance Audio Input Voltage reference Audio Input Level FM THD AM THD Picture/Sound Carrier Ratio (FM) Pin 11, 19 11, 19 7, 8 7, 8 10, 12 10, 12 1,2 4 1, 2 1, 2 15, 16 0.5 70 Min 4.5 52 10 50 70 330 84 1.0 80 59 4 1.5 Typ Max 5.5 Units V mA mV RMS VCC=5V Single ended into 50W Conditions
)80C,
)5.5V.
W
kHz kHz dBmV Vp-p % dB kHz See note 2 Weighted PAL 200kHz - 5.5MHz See note1 See note 1 See note 1, VCC = 4.5 to 5.5 V unmodulated into 50W
15, 16 17 17 17 1, 2 1.2 1, 2 10
2.5 25 2 0.88 1 1 13 20 1
kHz kW V Vp-p % % dB
VCC = 4.5 to 5.5V
Measured at pin 17 Q = 9, Df =
35kHz
Input level 880mV p-p R = 0, See note 3
SL5067 ELECTRICAL CHARACTERISTICS (cont.)
Tamb= -10C to VCC=)4.5V to These characteristics are guaranteed over the following conditions (unless otherwise stated). They apply within the specified ambient temperature and supply voltage ranges. Value Characteristics Sound Oscillator FM Deviation NOTES 1. 2. 3. 4. Pin 1, 2 Min Typ 250 Max Units kHz/V Conditions C = 120pF, L = 5.6mH (QL = 9)
)80C,
)5.5V.
Including external components effects May be increased by use of external resistor, see Fig. 3 May be adjusted by use of external resistor dependent on video content, see Fig. 4 The above measurements assume nominal 80% modulation depth on vision and sound carriers
ABSOLUTE MAXIMUM RATINGS
All voltages are referred to VEE=0V Value Parameter Supply Voltage Modulation index Video input Audio input FM/AM select Storage temperature DP20 thermal resistance, chip-to-ambient DP20 thermal resistance, chip-to-case MP20 thermal resistance, chip to ambient MP20 thermal resistance, chip-to-case Power consumption at 5.5V Pin 11, 19 3 4 17 18 Min -0.3 -0.3 -0.3 -0.3 -0.3 -55 Max 7 VCC+0.3 VCC+0.3 VCC+0.3 VCC+0.3 +125 78 30 93 34 300 Units V V V V V C C/W C/W C/W C/W mW Conditions
84dBmV
Power levels shown are relative to picture carrier fp typically
-13dB -16dB -47dB -65dB -70dB -70dB
fp
fp+(fs-fc) 1.57MHz
fc 4.43MHz
fs 6MHz
2xfc 8.86MHz
2xfs 12MHz
3xfs 18MHz
Fig. 3 Frequency spectrum above the Video picture carrier (QTANK = 9)
SL5067 VIDEO
The video signal is applied to pin 4 via a coupling capacitor, (see Fig.9). This capacitor provides both clamping and black level hold. The internal peak white AGC can cope with an input signal of between 0.5 and 1.5 volts peak to peak.The full 9.5 dB AGC range is handled within a 600mV span on this storage capacitor. Pin 3 (MOD INDEX) is used to control both RF carrier amplitude and video polarity, see Fig. 3. Since the video input is internally AGC'd, varying the carrier amplitude will also adjust the video modulation index, see Fig. 4. For example, for a negative modulation (PAL or NTSC) with an 80% modulation index, pin 3 should be set to 1.1Volts (see Fig. 4). This voltage corresponds to an unmodulated RF output level of 82dBmV, see Fig. 3. The Q factor of the coil must be high, e.g. >20 Good temperature stability can be achieved by the correct choice of temperature coefficients for Csound and Lsound. The Audio signal should be coupled into pin 17 via a 470nF capacitor. The maximum input level is 1 volts peak to peak. Selection of AM or FM sound is made via pin 18 (FMAMSEL). The DC value on this pin controls the level of the sound subcarrier. The crossover point between FM and AM sound occurs at CC (measured at pin 18). Below this voltage, the modulator is set to FM sound; above it to AM. Graphs for AM and FM sound subcarrier output levels are shown in Figs. 6 and 7. If AM sound is required, it is recommended that a modulated carrier is fed into the Audio input. Further details of this are mentioned at the end of the datasheet in the paragraph marked ``Positive Modulation"
1/2V
AUDIO
The sound IF oscillator can operate from 4.5MHz to 6.5MHz to cover all sound standards. The centre frequency is determined by the Sound IF Tank LC connected between pins 15 and 16. The centre frequency is given by.
MODULATED RF OUTPUT
The modulated RF outputs from pin 1 and pin 2 consist of open collectors which should be externally connected to VCC via 75W resistors. Great care must be taken with the decoupling of the supply to these outputs. Both outputs are suitable for driving either 75W line, or for connection to a balun or impedance matching transformer. This has the added benefit of minimising common mode coupling, thus giving improved RF performance.
f0
+ 2p 1LC
1770 + 2pf L + 1770
0
The Q factor of the TANK is given by. Q 2pf 0C
87 85 83 81
80dBmV
79 77 0.0 1.0 1.4 2.0 2.45 3.0 VOLTAGE SET ON PIN 3 4.0 5.0
Fig. 4. Picture carrier, unmodulated RF output level
SL5067
100 80.0 MOD 60.0 INDEX % (VIDEO) 40.0 20.0 0.00 0.0 NEGATIVE MODULATION
POSITIVE MODULATION
1.0 1.1 80% NEGATIVE
2.0 2.2
3.0
4.0 PIN 3 VOLTAGE
5.0
96% POSITIVE
Fig. 5. Modulation index as a function of pin 3 voltage
75 70
RF O/P LEVEL dBmV INTO 50W
65 60 55 60 45 0.0 1.0 PIN18 VOLTAGE 1.66V 2.0 ref to ground + - 3.0 PIN 18
Fig. 6 FM sound carrier amplitude dBmV.
70
AUDIO OUTPUT LEVEL dBmV INTO 50W
60
50
40 5V 4.0 PIN18 VOLTAGE 3.0 2.0
Fig. 7 AM sound carrier amplitude dBmV unmodulated
SL5067
SL5067 SL5067
FM/AM SEL AUDIO I/P SOUND TANK 220p 18 17 16 15 120p (6MHz) 5.6mH 470n AUDIO INPUT 220K VIDEO INPUT 75W 470nF 330n 3 4 5 VIDEO MODULATION INDEX SET VIDEO INPUT AGC HOLD
Fig. 8. Typical FM sound section
Fig. 9 Video input
VCC 120 1.2p BB405 1.5p 40nH BB405 1.5p 47K 47K 1.2p 4mA TUNING VOLTAGE 12 58W 13 45 58W 9 10 45 120 1 2
SL5067
5mA
Fig. 10 RF oscillator
Fig. 11 Modulated outputs
SL5067
1.2p 1.2p 9 10 1.5p 13 12 11 1.5p 100pF 100n VCC
21/2 turns 3mm
11/2 turns 3mm
100p BB405 5p6
22K 22K 10K 10n
VTUNE
NOTE:- both coils 24SWG
Fig. 12 UHF application
SL5067
Q=2 85 80 75 70 65 OUTPUT LEVEL (dBmV) UNTERMINATED 60 55 50 45 40 35 30 25 20 20 40 60 80
Q=8 PICTURE CARRIER
Q=16 480 440 400 SOUND SUBCARRIER 380 320 280 240 200 160 DEVIATION 120 80 40 0 FM DEVIATION (kHz/V)
3rd HARMONIC
100 120 140 160 180 200 220 240 260 280 SOUND TANK CAPACITANCE
Fig. 13 Sound oscillator harmonics v. tank capacitance (fSOUND =6.0MHz)
VCC 2 75 75 VCC 75W 100nF 10nF 1nF 330n 470nF 75W 1n 1n 10n NC NC NC NC 1.2p 100n +30V 1.5p 22K
1 2 3 4 5 6 7 8 9 10 20 19 18 17
MODULATED OUTPUT
10n
VIDEO INPUT
VCC
1nF
RV2 220p 470n AUDIO INPUT 220K
RV1
1 2 18 17 16
SL5067
4MHZ
16
5.6m
15 14 13 12 11
120p
SP5510
18p SDA SCL NC NC NC NC
3 4 5 6 7 8 9
LAUDIO CAUDIO 1.2p 1.5p VCC 100nF
15 14 13 12 11 10
2 turns 6mm
1 turn 6mm
22K 180n 39n 2N3904 10K BB405
100p
100pF 5p6
22K
10n
22K
NOTES:- RV1 adjusts the modulation index RV2 adjusts the picture carrier to sound carrier ratio In applications the potentiometers should be replaced by 1% fixed resistors connected between VCC and G ND The values chosen must reproduce the correct bias voltages on the relevant input pins
Fig.14 typical application showing video modulator with synthesised oscillator
SL5067 APPLICATION NOTES Overview
The key to good modulator performance is to ensure good and compact circuit layout with adequate grounding of all supplies. Earth loops must be avoided or kept as small as possible since RF coupling either through the air, or through the ground plane itself is the single most important factor in degrading modulator performance. Double sided board with a groundplane should be used, and all sensitive pins must be properly decoupled as close to the device as practicable.
Sound tank circuit
Care must also be taken with the layout of the sound tank, in order to minimise harmonics,and reduce coupling between the audio and video parts of the circuit. The sound tank must be situated as close to the device pins as possible. If this is not done, RF may couple into the sound tank, via the tracks connecting the sound oscillator to the inductor and capacitor. In practice, it is easiest to mount the sound tank capacitor close to, or directly on pin 15 and 16, with the inductor slightly further away. This appears to give the best linearity. In some cases where some coupling and/or distortion problems are occurring, the addition of small 2p2 capacitors from either side of the tank circuit to ground may improve both FM deviation and linearity. For optimum performance (in the FM case) the sound tank should be selected to give a Q of around 10. The circuits shown in the datasheet give a value of approximately 9, and are the suggested normalised values to be used. Lower values of Q will give greater FM deviation per volt input (kHz/Volt), but also increase the level of the 3rd harmonic of the sound subcarrier. This is shown in Fig. 10. The Q of the inductor chosen should be at least 2.5 times the Q of the tank circuit itself. It is not recommended that a Q of over 16 is used, as the amplitude of the sound subcarrier fundamental will start to decrease once a Q of approx 12 has been reached. Thus if a Q of 20 were used in order to give good harmonic performance, there would be an unacceptable trade off in terms of picture carrier to sound subcarrier ratio, which would be approx 20dB.
Oscillator design and layout
The oscillator should be kept as small as possible to minimise parasitics. It is recommended that the circuit diagram shown in these application notes is used if the entire UHF band is to be covered. For lower frequencies or for applications requiring less tuning range, component values can be adjusted. Surface mount components should be used throughout the circuit and particular care must be taken with placement as the two coils should be as close to the oscillator pins as possible.( See Figs. 16 and 17) For applications at low VHF frequencies, it is suggested that the values of the coupling capacitors on pins 9, 10, 11 and 12 are increased, 2.2pF capacitors (or greater) may be used for frequencies up to 500MHz but it must be remembered that the larger the coupling capacitor used, the smaller the tuning range will be, as the varactor diode capacitance will form a lower percentage of the total tuning capacitance of the loop. For fixed frequencies (or small tuning ranges) up to 100MHz, 15pF or 18pF capacitors may be used. Varactor tuning of the SL5067 should not be attempted unless the application either uses a synthesiser, or a temperature compensating network is used. The capacitance of most varactor diodes changes greatly with temperature, and this must be compensated for if the modulator is to remain on tune to the correct channel. For applications requiring tuning over only a few channels, an air variable capacitor plus appropriate temperature compensation may be used.
MISCELLANEOUS POINTS Board layout and decoupling
Good decoupling techniques must be used throughout with the use of surface mount components wherever possible. For best performance, all supplies and sensitive pins should be decoupled as close to the device as possible, with a combination of capacitors, say 100pF and 10nF to ground. The use of double sided board with a groundplane is strongly advised. This should be of particular help in the reduction of oscillator coupling.
Modulated outputs
Care must be taken with the routing of the modulated outputs and also with the mod index pin, pin3. It is suggested that pin 1 is used, and that the unused modulated output on pin 2 is terminated in a way which looks as physically and electrically similar to the used output on pin 1. Experiments have shown that a RF coupling problem can exist between pins 2 and 3. This manifests itself at frequencies over 600MHz in applications where pin 3 is not taken directly to ground. Good decoupling of pin 3 (with 10pF and 10nF) will help to reduce these effects. The modulated outputs must be routed away from the oscillator tank as there is danger of the local oscillator signal coupling directly into the modulated outputs. This will produce distortions in the modulated signal giving bad performance in such characteristics as differential phase and gain. For VHF and other applications below 500MHz RF coupling is not such a problem, however similar care should still be taken with layout in order to maximise device performance.
Mod index pin
As already stated, great care must be taken with the mod index pin, pin 3. This should be decoupled with chip components as close to the pin as possible. Ideally the mod index should be defined with a DC voltage, thus requiring the use of two external resistors, see Figs 4 and 5. It is also possible to define mod index through the use of a single resistor connected to ground or VCC depending on whether negative or positive modulation is required.
Synthesiser drive
It is suggested that any synthesiser (if used) is driven differentially. This is done by taking both of the prescaler outputs (pin 7 and 8) to the synthesiser via 1nF or 10nF capacitors.
Use of a balun
It is possible to further improve device performance with the use of a balun to remove the effects of common mode coupling. Although using a balun will add to component cost, it may be the only way to achieve acceptable performance at higher frequencies where common mode noise has made it impossible to achieve a low enough minimum power signal to give the necessary dynamic range in the output signal. A low cost balun wound on a ferrite bead former should be sufficient to provide adequate performance in the majority of applications.
FM/AM select
The voltage on the FM/AM select pin should be defined by two external resistors between vcc and ground, see Figs 6 and 7. The application diagram Fig. 14 shows a potentiometer, RV2 which is used to define the voltage on this pin in the demo board in practice it is suggested that in low total resistance value (5V or less) is used between VCC and GND since this will ensure a constant voltage on pin 18 irrespective of any small internal resistance variations between devices, thus ensuring a constant PC/SC ratio. It should be noted that the sound subcarrier level is referenced to the AGC sidebands rather
SL5067
than the picture carrier itself. Thus if the picture carrier level is reduced by using a resistor on pin 3 (mod index set), the level of the sound subcarrier will not change. This should be remembered when setting up a modulator to give the desired modulation index and vision/sound carrier ratio. device into these modes, it should be noted that the SL5067 will not perform to full SECAM specifications. Use of AM sound may produce sound-in-vision interference at higher modulation depths. It should be possible, however to AC couple in modulated audio. If this is attempted, the sound tank circuit on pins 15 and 16 would not be required. The modulated audio signal should be fed into the Audio input pin (pin 17) via a 470nF capacitor. The FM/AM select pin can be used as a gain control pin, but will not switch the device between FM and AM modes.
POSITIVE MODULATION
Several references are made in the text to positive video modulation and AM sound. Whilst it is possible to switch the
SL5067
VIDEO I/P +5V 75R 10nF 75R 2K 100nF 3 18 470nF RV3 120pF 5u6H 2K AM MOD INDEX 17 16 15 14 1p2 8 13 12 11 100pF 100nF NC 10K NC BB405 10nF 100pF 22K 1 TURN AUDIO I/P 5p6 22K 220K 220pF 1p5 PRE-EMPHASIS AM 9 NC NC 1p5 10 FM 2N3904 1nF 75R 470nF 5 6 10nF 7 10nF 1p2 RV1 MOD INDEX 339nF 4 100pF 10nF 2 2K 19 RV2 1 20 PC/SC RATIO 75R 100nF 100pF
MODULATED O/P
+30V 22K
+5V
47nF
220nF
22K
1
18
4MHz
18pF
2
17
S L 5 0 6 7
FM-AM SOUND SELECT
3
16
SDA
4
15
SCL
5
14
NC
6
S P 5 5 1 0
13
NC
7
12
NC
8
11
NC
9
10
NOTE +5V 10nF
2 TURNS BOTH INDUCTORS ARE 6mm DIA
NOTES:
RV1 adjusts the modulation index RV2 adjusts the picture carrier to sound carrier ratio RV3 adjusts the AM modulation path In applications the potentiometers should be replaced by 1% fixed resistors connected between Vcc and Gnd. The values chosen must reproduce the correct bias voltages on the relevent input pins. For AM sound applications the pre-emphasis cpmponents are bypassed, the I/P being connected to pin 17 via 470nF. For FM sound applications the pre=emphasis components are switched in and RV3 is switched out.
Fig. 16 Video modular test board circuit diagram
SL5067
TRACK LAYOUT
RV1 RV3 RV2 SL5067
SP5510
SL5067 TEST BOARD LAYOUT
Fig. 17
SL5067 PACKAGE DETAILS
Dimensions are shown thus: mm (in). For further package information please contact your local Customer Service Centre
27.94/1.100 MAX
20 LEAD PLASTIC DIL DP20
7.11 (0.280) MAX 1.14/1.65 (0.045/0.065)
5.08 (0.200) MAX SEATING PLANE 0.51 (0.020) MIN 3.05 (0.120) MIN 0.23/0.41 (0.009/0.016) 0.38/0.61 (0.015/0.024) 2.54 (0.100) NOM 7.62 (0.300) NOM
12.60/13.00 (0.496/0.512)
20 LEAD MINIATURE PLASTIC MP20
0.74(0.029) AT 4 PLACES
PIN 1 IDENTIFICATION
1.27 (0.050) NOM PIN SPACING 0.25/0.51 2.36/2.64 (0.093/0.104)
(0.010/0.020) X45 8MAX
7.70/7.80 0.291/0.299)
0.23/0.33
(0.009/0.013)
0.41/1.27
(0.016/0.050)
0.36/0.48 (0.014/0.019)
0.10/0.30 (0.004/0.012)
10.00/10.64 (0.394/0.419)
SL5067
HEADQUARTERS OPERATIONS GEC PLESSEY SEMICONDUCTORS Cheney Manor, Swindon, Wiltshire United Kingdom SN2 2QW. Tel: (0793) 518000 Fax: (0793) 518411
GEC PLESSEY SEMICONDUCTORS P.O. Box 660017 1500 Green Hills Road, Scotts Valley, California 95067-0017, United States of America. Tel: (408) 438 2900 Fax: (408) 438 5576
CUSTOMER SERVICE CENTRES F FRANCE & BENELUX Les Ulis Cedex Tel: (1) 64 46 23 45 Tx: 602858F Fax: (1) 64 46 06 07 F GERMANY Munich Tel: (089) 3609 06 0 Tx: 523980 Fax: (089) 3609 06 55 F ITALY Milan Tel: (02) 66040867 Fax: (02) 66040993 F JAPAN Tokyo Tel: (03) 3296-0281 Fax: (03) 3296-0228 F NORTH AMERICA Integrated Circuits and Microwave Products, Scotts Valley, USA Tel: (408) 438 2900 Fax: (408) 438 7023 Hybrid Products, Farmingdale, USA Tel: (516) 293 8686 Fax: (516) 293 0061 F SOUTH EAST ASIA Singapore Tel: (65) 3827708 Fax: (65) 3828872 F SWEDEN Stockholm Tel: 46 8 7029770 Fax: 46 8 6404736 F UNITED KINGDOM & SCANDINAVIA Swindon Tel: (0793) 518510 Tx: 444410 Fax: (0793) 518582 These are supported by Agents and Distributors in major countries world-wide. Publication No. D.S. 3802 Issue No. 1.3 January 1994
E GEC Plessey Semiconductors 1994
This publication is issued to provide information only, which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. The Company reserves the right to alter without proir knowledge the specification, design, price of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. These products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to the Company's conditions of sale, which are available on request.

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