LM1203N

LM1203 RGB Video Amplifier System January 1996 LM1203 RGB Video Amplifier System General Description The LM1203 is a wideband video amplifier system intended for high resolution RGB color monitor applications In addition to three matched video amplifiers the LM1203 contains three gated differential input black level clamp comparators for brightness control and three matched attenuator circuits for contrast control Each video amplifier contains a gain set or ‘‘Drive’’ node for setting maximum system gain (Av e 4 to 10) as well as providing trim capability The LM1203 also contains a voltage reference for the video inputs For high resolution monochrome monitor applications see the LM1201 Video Amplifier System datasheet Features Y Y Y Y Y Y b 3dB) Three wideband video amplifiers (70 MHz Inherently matched ( g 0 1 dB or 1 2%) attenuators for contrast control Three externally gated comparators for brightness control Provisions for independent gain control (Drive) of each video amplifier Video input voltage reference Low impedance output driver Block and Connection Diagram TL H 9178 – 1 FIGURE 1 Order Number LM1203N See NS Package Number NA28F C1996 National Semiconductor Corporation TL H 9178 RRD-B30M56 Printed in U S A Absolute Maximum Ratings If Military Aerospace specified devices are required please contact the National Semiconductor Sales Office Distributors for availability and specifications Supply Voltage VCC Pins 1 13 23 28 (Note 1) 13 5V Voltage at Any Input Pin VIN VCC t VIN t GND Video Output Current I16 20 or 25 28 mA 2 5W Power Dissipation PD (Above 25 C) Derate Based on iJA and TJ Thermal Resistance iJA 50 C W Junction Temperature TJ 150 C Storage Temperature Range TSTG Lead Temperature (Soldering 10 sec ) b 65 C to a 150 C 265 C ESD susceptibility 1 kV Human body model 100 pF discharged through a 1 5 kX resistor Operating Ratings (Note 9) Temperature Range Supply Voltage (VCC) 0 C to 70 C 10 8V s VCC s 13 2V Electrical Characteristics See Test Circuit (Figure 2) DC Static Tests S17 Label Is V11 Parameter Supply Current Video Input Reference Voltage TA e 25 C VCC1 e VCC2 e 12V 21 26 Open V12 e 6V V14 e 0V V15 e 2 0V unless otherwise stated Conditions VCC 1 only Typ 73 24 Any One Amplifier Clamp Comparators On Clamp Comparators Off V14 e 0V V14 e 12V V5 8 or 10 e 0V V5 8 or 10 e 5V V5 8 or 10 e 0V V5 8 or 10 e 5V Between Any Two Amplifiers V15 e 2V Between Any Two Amplifiers V15 e 4V 50 12 16 b0 5 Tested Limit (Note 2) 90 0 22 26 Design Limit (Note 3) Units (Limits) mA(max) V(min) V(max) mA(max) V(max) V(min) mA(max) mA(max) mA(min) mA(min) V(max) V(min) mV(max) mV(max) lb V14 l V14 h I14 l I14 h lclamp a lclampb Vol Voh DVo(2V) DVo(4V) Video Input Bias Current Clamp Gate Low Input Voltage Clamp Gate High Input Voltage Clamp Gate Low Input Current Clamp Gate High Input Current Clamp Cap Charge Current Clamp Cap Discharge Current Video Output Low Voltage Video Output High Voltage Video Output Offset Voltage Video Output Offset Voltage 20 08 20 b5 0 0 005 850 b 850 1 500 b 500 09 89 g0 5 1 25 82 g 50 g0 5 g 50 AC Dynamic Tests S17 Symbol Av max DAv 5V DAv 2V Av match DAv track1 DAv track2 THD f (b3 dB) tr tf Parameter Video Amplifier Gain Attenuation Attenuation 5V 2V 21 26 Closed V14 e 0V V15 e 4V unless otherwise stated Conditions V12 e 12V VIN e 560 mVp-p Ref Av max V12 e 5V Ref Av max V12 e 2V Typ 60 b 10 b 40 g0 5 g0 1 g0 3 g0 5 g0 7 Tested Limit (Note 2) 45 Design Limit (Note 3) Units (Limits) V V(min) dB dB dB dB(max) dB(max) % MHz ns ns Absolute gain match Av max V12 e 12V (Note 5) V12 e 5V (Notes 5 8) V12 e 2V (Notes 5 8) V12 e 3V VO e 1 Vp-p V12 e 12V VO e 100 mVrms VO e 4 Vp-p VO e 4 Vp-p Gain change between amplifiers Gain change between amplifiers Video Amplifier Distortion Video Amplifier Bandwidth (Notes 4 6) Output Rise Time (Note 4) Output Fall Time (Note 4) 05 70 5 7 http www national com 2 AC Dynamic Tests S17 Symbol Vsep 10 kHz Vsep 10 MHz Parameter 21 26 Closed V14 e 0V V15 e 4V unless otherwise stated (Continued) Conditions V12 e 12V (Note 7) V12 e 12V (Notes 4 7) Typ b 65 b 46 Tested Limit (Note 2) Design Limit (Note 3) Units dB dB Video Amplifier 10 kHz Isolation Video Amplifier 10 MHz Isolation Note 1 VCC supply pins 1 13 23 28 must be externally wired together to prevent internal damage during VCC power on off cycles Note 2 These parameters are guaranteed and 100% production tested Note 3 Design limits are guaranteed (but not 100% production tested) These limits are not used to calculate outgoing quality levels Note 4 When measuring video amplifier bandwidth or pulse rise and fall times a double sided full ground plane printed circuit board without socket is recommended Video Amplifier 10 MHz isolation test also requires this printed circuit board Note 5 Measure gain difference between any two amplifiers VIN e 1 Vp-p Note 6 Adjust input frequency from 10 kHz (Avmax ref level) to the b 3 dB corner frequency (f b 3 dB) Note 7 Measure output levels of the other two undriven amplifiers relative to driven amplifier to determine channel separation Terminate the undriven amplifier inputs to simulate generator loading Repeat test at fIN e 10 MHz for Vsep e 10 MHz Note 8 DAv track is a measure of the ability of any two amplifiers to track each other and quantifies the matching of the three attenuators It is the difference in gain change between any two amplifiers with the Contrast Voltage V12 at either 5V or 2V measured relative to an Av max condition V12 e 12V For example at Av max the three amplifiers gains might be 17 4 dB 16 9 dB and 16 4 dB and change to 7 3 dB 6 9 dB and 6 5 dB respectively for V12 e 5V This yields the measured typical g 0 1 dB channel tracking Note 9 Operating Ratings indicate conditions for which the device is functional See Electrical Specifications for guaranteed performance limits Peaking capacitors See Frequency Response using various peaking cups graph on next page TL H 9178 – 2 FIGURE 2 LM1203 Test Circuit 3 http www national com Typical Performance Characteristics Contrast vs Frequency Crosstalk vs Frequency TL H 9178–11 TL H 9178 – 12 Frequency Response Using Various Peaking Caps Attenuation vs Contrast Voltage TL H 9178 – 14 TL H 9178–13 Pulse Response Rise Fall Times Vert e 1V Div Horiz e 10 ns Div – – GND TL H 9178 – 15 http www national com 4 TL H 9178 – 3 FIGURE 3 LM1203 Typical Application 30X resistors are added to the input pins for protection against current surges coming through the 10 mF input capacitors By increasing these resistors to well over 100X the rise and fall times of the LM1203 can be increased for EMI considerations 5 http www national com Applications Information Figure 4 shows the block diagram of a typical analog RGB color monitor The RGB monitor is used with CAD CAM work stations PC’s arcade games and in a wide range of other applications that benefit from the use of color display terminals The RGB color monitor characteristics may differ in such ways as sweep rates screen size CRT color trio spacing (dot pitch) or in video amplifier bandwidths but will still be generally configured as shown in Figure 4 Separate horizontal and vertical sync signals may be required or they may be contained in the green video input signal The video input signals are usually supplied by coax cable which is terminated in 75X at the monitor input and internally ac coupled to the video amplifiers These input signals are approximately 1 volt peak to peak in amplitude and at the input of the high voltage video section approximately 6V peak to peak At the cathode of the CRT the video signals can be as high as 60V peak to peak One important requirement of the three video amplifiers is that they match and track each other over the contrast and brightness control range The Figure 4 block labeled ‘‘VIDEO AMPLIFICATION WITH GAIN AND DC CONTROL’’ describes the function of the LM1203 which contains the three matched video amplifiers contrast control and brightness control TL H 9178 – 4 FIGURE 4 Typical RGB Color Monitor Block Diagram http www national com 6 Circuit Description Figure 5 is a block diagram of one of the video amplifiers along with the contrast and brightness controls The contrast control is a dc-operated attenuator which varies the ac gain of all three amplifiers simultaneously while not introducing any signal distortions or tracking errors The brightness control function requires a ‘‘sample and hold’’ circuit (black level clamp) which holds the dc bias of the video amplifiers and CRT cathodes constant during the black level reference portion of the video waveform The clamp comparator when gated on during this reference period will charge or discharge the clamp capacitor until the plus input of the clamp comparator matches that of the minus input voltage which was set by the brightness control Figure 6 is a simplified schematic of one of the three video amplifiers along with the recommended external components The IC pin numbers are circled with all external components shown outside of the dashed line The video input is applied to pin 6 via the 10 mF coupling capacitor DC bias to the video input is through the 10 kX resistor which is connected to the 2 4V reference at pin 11 The low frequency roll-off of the amplifier is set by these two components Transistor Q1 buffers the video signal to the base of Q2 The Q2 collector current is then directed to the VCC 1 supply directly or through the 1k load resistor depending upon the differential DC voltage at the bases of Q3 and Q4 The Q3 and Q4 differential base voltage is determined by the contrast control circuit which is described below RF decoupling capacitors are required at pins 2 and 3 to insure high frequency isolation between the three video amplifiers which share these common connections The black level dc voltage at the collector of Q4 is maintained by Q5 and Q6 which are part of the black level clamp circuit also described below The video signal appearing at the collector of Q4 is then buffered by Q7 and level shifted down by Z1 and Q8 to the base of Q9 which will then provide additional system gain TL H 9178 – 5 FIGURE 5 Block Diagram of LM1203 Video Amplifier with Contrast and Black Level Control 7 http www national com http Circuit Description (Continued) www national com TL H 9178 – 6 8 FIGURE 6 Simplified LM1203 Video Amplifier Section with Recommended External Components Circuit Description (Continued) The ‘‘Drive’’ pin will allow the user to trim the Q9 gain of each amplifier to correct for differences in the CRT and high voltage cathode driver gain stages A small capacitor (33 pF) at this pin will extend the high frequency gain of the video amplifier by compensating for some of the internal high frequency roll off To use this capacitor and still provide variable gain adjustment the 51X and series 100X pot should be used with the red and green drive pins The 91X resistor used with the blue drive pin will set the system gain to approximately 6 2 and allow adjustment of the red and green gains to 6 2 plus or minus 25% The video signal at the collector of Q9 is buffered and level shifted down by Q10 and Q11 to the base of the output emitter follower Q12 Between the emitter of Q12 and the video output pin is a 40X resistor which was included to prevent spurious oscillations when driving capacitive loads An external emitter resistor must be added between the video output pin and ground The value of this resistor should not be less than 390X or package power limitations may be exceeded when worst case (high supply max supply current max temp) calculations are made If negative going pulse slewing is a problem because of high capacitive loads (l10 pF) a more efficient method of emitter pull down would be to connect a suitable resistor to a negative supply voltage This has the effect of a current source pull down when the minus supply voltage is b12V and the emitter current is approximately 10 mA The system gain will also increase slightly because less signal will be lost across the internal 40X resistor Precautions must be taken to prevent the video output pin from going below ground because IC substrate currents may cause erratic operation The collector currents from the video output transistors are returned to the power supply at VCC 2 pin 23 When making power dissipation calculations note that the data sheet specifies only the VCC 1 supply current at 12V The IC power dissipation contribution of VCC 2 is dependent upon the video output emitter pull down load In applications that require video amplifier shut down because of fault conditions detected by monitor protection circuits pin 11 and the wiper arms of the contrast and brightness controls can be grounded without harming the IC This assumes some series resistance between the top of the control pots and VCC Figure 7 shows the internal construction of the pin 11 2 4V reference circuit which is used to provide temperature and supply voltage tracking compensation for the video amplifier inputs The value of the external DC biasing resistors should not be larger than 10 kX because minor differences in input bias currents to the individual video amplifiers may cause offsets in gain TL H 9178 – 7 FIGURE 7 LM1203 Video Input Voltage Reference and Contrast Control Circuits 9 http www national com Circuit Description (Continued) Figure 7 also shows how the contrast control circuit is configured Resistors R23 24 diodes D3 4 and transistor Q13 are used to establish a low impedance zero TC half supply voltage reference at the base of Q14 The differential amplifier formed by Q15 16 and feedback transistor Q17 along with resistors R27 28 establish a diferential base voltage for Q3 and Q4 in Figure 6 When externally adding or subtracting current from the collector of Q16 a new differential voltage is generated that reflects the change in the ratio of currents in Q15 and Q16 To provide voltage control of the Q16 current resistor R29 is added between the Q16 collector and pin 12 A capacitor should be added from pin 12 to ground to prevent noise from the contrast control pot from entering the IC Figure 8 is a simplified schematic of the clamp gate and clamp comparator sections of the LM1203 The clamp gate circuit consists of a PNP input buffer transistor (Q18) a PNP emitter coupled pair referenced on one side to 2 1V (Q19 20) and an output switch (Q21) When the clamp gate input at pin 14 is high (l1 5V) the Q21 switch is on and shunts the I1 850 mA current to ground When pin 14 is low ( k1 3V) the Q21 switch is off and the I1 850 mA current source is mirrored or ‘‘turned around’’ by reference diode D5 and Q26 to provide a 850 mA current source for the clamp comparator(s) The inputs to the comparator are similar to the clamp gate input except that an NPN emitter coupled pair is used to control the current which will charge or discharge the clamp capacitors at pins 5 8 or 10 PNP transistors are used at the inputs because they offer a number of advantages over NPNs PNPs will operate with base voltages at or near ground and will usually have a greater reverse emitter base breakdown voltage (BVebo) Because the differential input voltage to the clamp comparator during the video scan period could be greater than the BVebo of NPN transistors a resistor (R34) with a value one half that of R33 or R35 is connected between the bases of Q23 and Q27 This resistor will limit the maximum differential input to Q24 25 to approximately 350 mV The clamp comparator common mode range is from ground to approximately 9V and the maximum differential input voltage is VCC and ground TL H 9178 – 8 FIGURE 8 Simplified Schematic of LM1203 Clamp Gate and Clamp Comparator Circuits http www national com 10 Additional Applications of the LM1203 Figure 9 shows how the LM1203 can be set up as a video buffer which could be used in low cost video switcher applications Pin 14 is tied high to turn off the clamp comparators The comparator input pins should be grounded as shown Sync tip (black level if sync is not included) clamping is provided by diodes at the amplifier inputs Note that the clamp cap pins are tied to the Pin 11 2 4V reference This was done along with the choice of 200X for the drive pin resistor to establish an optimum DC output voltage The contrast control (Pin 12) will provide the necessary gain or attenuation required for channel balancing Changing the contrast control setting will cause minor DC shifts at the amplifier output which will not be objectionable as the output is AC coupled to the load The dual NPN PNP emitter follower will provide a low impedance output drive to the AC coupled 75X output impedance setting resistor The dual 500 mF capacitors will set the low frequency response to approximately 4 Hz TL H 9178 – 9 FIGURE 9 RGB Video Buffer with Diode Sync Tip Clamps and 75X Cable Driver 11 http www national com Additional Applications of the LM1203 (Continued) When diode D4 at Pin 11 is switched to ground the input video signals will be DC shifted down and clamped at a voltage near ground (approximately 250 mV) This will disable the video amplifiers and force the output DC level low The DC outputs from other similarly configured LM1203s could overide this lower DC level and provide the output signals to the 75X cable drivers In this case any additional LM1203s would share the same 390X output resistor The maximum DC plus peak white output voltage should not be allowed to exceed 7V because the ‘‘off’’ amplifier output stage could suffer internal zener damage See Figure 3 and text for a description of the internal configuration of the video amplifier Figure 10 shows the configuration for a three channel high frequency amplifier with non gated DC feedback Pin 14 is tied low to turn on the clamp comparators (feedback amplifiers) The inverting inputs (Pins 17 21 26) are connected to the amplifier outputs from a low pass filter Additional low frequency filtering is provided by the clamp caps The drive resistors can be made variable or fixed at values between 0 and 300X Maximum output swings are achieved when the DC output is set to approximately 4V The high frequency response will be dependent upon external peaking at the drive pins TL H 9178 – 10 FIGURE 10 Three Channel High Frequency Amplifier with Non-gated DC Feedback (Non-video Applications) http www national com 12 TL H 9178 – 16 FIGURE 11 LM1203 LM1881 Application Circuit for PC Board 13 http www national com http www national com PC Board with Components 14 TL H 9178 – 17 15 http www national com LM1203 RGB Video Amplifier System Physical Dimensions inches (millimeters) unless otherwise noted Lit 107315 28-Lead Molded Dual-In-Line Package (N) Order Number LM1203N NS Package Number NA28F LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL SEMICONDUCTOR CORPORATION As used herein 1 Life support devices or systems are devices or systems which (a) are intended for surgical implant into the body or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user National Semiconductor Corporation 1111 West Bardin Road Arlington TX 76017 Tel 1(800) 272-9959 Fax 1(800) 737-7018 2 A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness http www national com National Semiconductor Europe Fax a49 (0) 180-530 85 86 Email europe support nsc com Deutsch Tel a49 (0) 180-530 85 85 English Tel a49 (0) 180-532 78 32 Fran ais Tel a49 (0) 180-532 93 58 Italiano Tel a49 (0) 180-534 16 80 National Semiconductor Hong Kong Ltd 13th Floor Straight Block Ocean Centre 5 Canton Rd Tsimshatsui Kowloon Hong Kong Tel (852) 2737-1600 Fax (852) 2736-9960 National Semiconductor Japan Ltd Tel 81-043-299-2308 Fax 81-043-299-2408 National does not assume any responsibility for use of any circuitry described no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications