LM6588MA

LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 LM6588 TFT-LCD Quad, 16V RRIO High Output Current Operational Amplifier Check for Samples: LM6588 FEATURES DESCRIPTION • The LM6588 is a low power, high voltage, rail-to-rail input-output amplifier ideally suited for LCD panel VCOM driver and gamma buffer applications. The LM6588 contains four unity gain stable amplifiers in one package. It provides a common mode input ability of 0.5V beyond the supply rails, as well as an output voltage range that extends to within 50mV of either supply rail. With these capabilities, the LM6588 provides maximum dynamic range at any supply voltage. Operating on supplies ranging from 5V to 16V, while consuming only 750μA per amplifier, the LM6588 has a bandwidth of 24MHz (−3dB). 1 23 • • • • • • • • • • • • (VS = 5V, TA = 25°C Typical Values Unless Specified) Input Common Mode Voltage 0.5V Beyond Rails Output Voltage Swing (RL = 2kΩ) 50mV from Rails Output Short Circuit Current ±200mA Continuous Output Current 75mA Supply Current (Per Amp, No Load) 750μA Supply Voltage Range 5V to 16V Unity Gain Stable −3dB Bandwidth (AV = +1) 24MHz Slew Rate 11V/μSec Settling Time 270ns SOIC-14 and TSSOP-14 Package Manufactured in TI’s State-of-the-art Bonded Wafer, Trench Isolated Complementary Bipolar VIP10™ Technology for High Performance at Low Power Levels The LM6588 also features fast slewing and settling times, along with a high continuous output capability of 75mA. This output stage is capable of delivering approximately 200mA peak currents in order to charge or discharge capacitive loads. These features are ideal for use in TFT-LCDs. The LM6588 is available in the industry standard 14pin SOIC package and in the space-saving 14-pin TSSOP package. The amplifiers are specified for operation over the full −40°C to +85°C temperature range. APPLICATIONS • • • LCD Panel VCOM Driver LCD Panel Gamma Buffer LCD Panel Repair Amp Test Circuit Diagram 300: 3k: MEASURE CURRENT 8V 10: + 10: 10: 10: +2.5V -8V 10nF 10nF 10nF 10nF MEASURE VOLTAGE -2.5V ±2.5V SQUARE WAVE 1 2 3 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. VIP10 is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2003–2013, Texas Instruments Incorporated LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. Absolute Maximum Ratings (1) (2) ESD Tolerance (3) Human Body Model Machine Model 2.5KV 250V Supply Voltage (V+ - V−) 18V Differential Input Voltage ±5.5V Output Short Circuit to Ground (4) Continuous Storage Temperature Range −65°C to 150°C Input Common Mode Voltage V− to V+ Junction Temperature (1) (2) (3) (4) (5) (5) 150°C Absolute maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is intended to be functional, but specific performance is not ensured. For ensured specifications and the test conditions, see the Electrical Characteristics. If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and specifications. For testing purposes, ESD was applied using human body model, 1.5kΩ in series with 100pF. Applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated ambient temperature can result in exceeding the maximum allowed junction temperature of 150°C The maximum power dissipation is a function of TJ(MAX), θJA, and TA. The maximum allowable power dissipation at any ambient temperature is PD = (TJ(MAX) - TA)/ θJA . All numbers apply for packages soldered directly onto a PC board. Operating Ratings (1) 4V ≤ VS ≤ 16V Supply Voltage −40°C to +85°C Temperature Range Thermal Resistance (θJA) (1) 2 SOIC-14 145°C/W TSSOP-14 155°C/W Absolute maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is intended to be functional, but specific performance is not ensured. For ensured specifications and the test conditions, see the Electrical Characteristics. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 16V DC Electrical Characteristics (1) Unless otherwise specified, all limits ensured for at TJ = 25°C, VCM = ½VS and RL = 2kΩ. Boldface limits apply at the temperature extremes. Symbol Parameter VOS Input Offset Voltage TC VOS Input Offset Voltage Average Drift IB Input Bias Current IOS Input Offset Current RIN Input Resistance CMRR Common Mode Rejection Ratio Conditions Min (2) Typ (3) Max (2) Units 0.7 4 6 mV 5 −0.3/+0.3 ±1 ±7 16 150 300 Common Mode 20 Differential Mode 0.5 VCM = 0 to +16V 75 70 103 VCM = 0 to 14.5V 78 72 103 80 75 103 PSRR Power Supply Rejection Ratio VCM = ±1V CMVR Input Common-Mode Voltage Range CMRR > 50dB AV Large Signal Voltage Gain (4) RL = 2kΩ, VO = 0.5 to +15.5V VO Output Swing High RL = 2kΩ Output Swing Low RL = 2kΩ Output Short Circuit Current (5) Sourcing 170 230 Sinking 170 230 ISC ICONT IS (1) (2) (3) (4) (5) (6) Continuous Output Current (6) 16.2 0 16 80 75 108 15.8 15.6 15.9 μA nA MΩ dB dB −0.2 V dB V 0.100 Sourcing 40 Sinking 40 Supply Current (per Amp) μV/°C 800 0.200 mA mA 1200 1500 μA Electrical table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of the device such that TJ = TA. No specification of parametric performance is indicated in the electrical tables under conditions of internal self heating where TJ > TA. See applications section for information on temperature de-rating of this device. All limits are specified by testing or statistical analysis. Typical values represent the most likely parametric norm. Large signal voltage gain is the total output swing divided by the input signal required to produce that swing. Continuous operation at these output currents will exceed the power dissipation ability of the device Power dissipation limits may be exceeded if all four amplifiers source or sink 40mA. Voltage across the output transistors and their output currents must be taken into account to determine the power dissipation of the device Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 3 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com 16V AC Electrical Characteristics (1) Unless otherwise specified, all limits ensured for at TJ = 25°C, VCM = ½VS and RL = 2kΩ. Boldface limits apply at the temperature extremes. Symbol SR Min (2) Typ (3) AV = +1, VIN = 10VPP 8 15 V/μs 15.4 MHz AV = +1 10 24 MHz 61 deg 780 ns Parameter Slew Rate (4) Conditions Unity Gain Bandwidth Product −3dB Frequency Max (2) Units Φm Phase Margin ts Settling Time (0.1%) AV = −1, AO = ±5V, RL = 500Ω tp Propagation Delay AV = −2, VIN = ±5V, RL = 500Ω 20 ns HD2 2nd Harmonic Distortion FIN = 1MHz (5) VOUT = 2VPP −53 dBc HD3 3rd Harmonic Distortion FIN = 1MHz (5) VOUT = 2VPP −40 dBc en Input-Referred Voltage Noise f = 10kHz 23 nV/√Hz (1) (2) (3) (4) (5) 4 Electrical table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of the device such that TJ = TA. No specification of parametric performance is indicated in the electrical tables under conditions of internal self heating where TJ > TA. See applications section for information on temperature de-rating of this device. All limits are specified by testing or statistical analysis. Typical values represent the most likely parametric norm. Slew rate is the average of the raising and falling slew rates. Harmonics are measured with AV = +2 and RL = 100Ω and VIN = 1VPP to give VOUT = 2VPP. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 5V DC Electrical Characteristics (1) Unless otherwise specified, all limits ensured for at TJ = 25°C, VCM = ½VS and RL = 2kΩ. Boldface limits apply at the temperature extremes. Symbol Parameter Conditions Min (2) Typ (3) Max (2) Units 4 6 mV VOS Input Offset Voltage 0.7 TC VOS Input Offset Voltage Average Drift 10 IB Input Bias Current IOS Input Offset Current RIN Input Resistance CMRR Common Mode Rejection Ratio −0.3/+0.3 ±1 ±7 μA 20 150 300 nA Common Mode 20 Differential Mode 0.5 VCM Stepped from 0 to 5V 70 66 105 VCM Stepped from 0 to 3.5V 75 70 105 80 75 92 PSRR Power Supply Rejection Ratio VS = VCC = 3.5V to 5.5V CMVR Input Common-Mode Voltage Range CMRR > 50dB AV Large Signal Voltage Gain (4) RL = 2kΩ, VO = 0 to 5V VO Output Swing High (5) RL = 2kΩ Output Swing Low (5) RL = 2kΩ Output Short Circuit Current (6) Sourcing 160 200 Sinking 160 200 ISC ICONT IS (1) (2) (3) (4) (5) (6) (7) Continuous Output Current (7) 5.2 0.0 5.0 80 75 106 4.85 4.7 4.95 MΩ dB dB −0.2 V dB V 0.05 Sourcing 75 Sinking 75 Supply Current (per Amp) μV/°C 750 0.15 mA mA 1000 1250 μA Electrical table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of the device such that TJ = TA. No specification of parametric performance is indicated in the electrical tables under conditions of internal self heating where TJ > TA. See applications section for information on temperature de-rating of this device. All limits are specified by testing or statistical analysis. Typical values represent the most likely parametric norm. Large signal voltage gain is the total output swing divided by the input signal required to produce that swing. The open loop output current is specified, by the measurement of the open loop output voltage swing. Continuous operation at these output currents will exceed the power dissipation ability of the device Power dissipation limits may be exceeded if all four amplifiers source or sink 40mA. Voltage across the output transistors and their output currents must be taken into account to determine the power dissipation of the device Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 5 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com 5V AC Electrical Characteristics (1) Unless otherwise specified, all limits ensured for at TJ = 25°C, VCM = ½VS and RL = 2kΩ. Boldface limits apply at the temperature extremes. Symbol SR Parameter Slew Rate Min (2) Conditions (4) AV = +1, VIN = 3.5VPP Unity Gain Bandwidth Product −3dB Frequency AV = +1 10 Typ (3) Max (2) Units 11 V/μs 15.3 MHz 24 MHz 56 deg 270 ns Φm Phase Margin ts Settling Time (0.1%) AV = −1, VO = ±1V, RL = 500Ω tp Propagation Delay AV = −2, VIN = ±1V, RL = 500Ω 21 ns HD2 2nd Harmonic Distortion FIN = 1MHz (5) VOUT = 2VPP −53 dBc HD3 3rd Harmonic Distortion FIN = 1MHz (5) VOUT = 2VPP −40 dBc en Input-Referred Voltage Noise f = 10kHz 23 nV/√Hz (1) (2) (3) (4) (5) Electrical table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of the device such that TJ = TA. No specification of parametric performance is indicated in the electrical tables under conditions of internal self heating where TJ > TA. See applications section for information on temperature de-rating of this device. All limits are specified by testing or statistical analysis. Typical values represent the most likely parametric norm. Slew rate is the average of the raising and falling slew rates. Harmonics are measured with AV = +2 and RL = 100Ω and VIN = 1VPP to give VOUT = 2VPP. Connection Diagram 14-Pin SOIC/TSSOP 14 1 OUT A IN A- OUT D 2 13 IN D- 3 12 IN D+ IN A+ V + 4 11 5 10 IN C+ IN B+ IN B- - V 6 9 IN C- 7 8 OUT C OUT B Figure 1. Top View 6 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 Typical Performance Characteristics Unless otherwise specified, all limits ensured for TJ = 25°C, VCM = 1/2VS and RL = 2kΩ. Gain Phase vs. Temperature (VS = 5V) Gain Phase vs. Temperature (VS = 16V) 100 100 90 90 90 80 80 -40°C 50 40 GAIN 30 30 85°C 10 10 0 -10 0 -10 -20 100M -20 VS = 5V -20 1M 10M 100k FREQUENCY (Hz) 10k 0 -10 VS = 16V 1M 100k 10k FREQUENCY (Hz) Figure 3. Gain Phase vs. Capacitive Loading (VS = 5V) Gain Phase vs. Capacitive Loading (VS = 16V) 100 90 80 80 PHASE 70 70 70 60 60 60 0pF 50 50 40 GAIN 10pF 30 30 30pF 20 10 0pF VS = 5V -20 1M 100k 10M 100 90 PHASE 80 0pF 50 GAIN 40 10pF 30pF 20 20 10 10 0 -10 0 -10 -20 100M -20 20 10 VS = 16V 10k 0pF 1M 100k 10M 0 -10 -20 100M FREQUENCY (Hz) Figure 5. PSRR (VS = 5V) PSRR (VS = 16V) 110 110 100 100 90 90 +PSRR +PSRR 80 PSRR (dB) 80 PSRR (dB) 40 30 30 Figure 4. 70 -PSRR 60 50 70 -PSRR 60 50 40 40 30 30 10 10 70 60 50 FREQUENCY (Hz) 20 -20 100M 10M Figure 2. GAIN (dB) GAIN (dB) 10 -40°C 90 10k 30 20 100 0 -10 40 85°C 90 40 50 25°C 100 80 60 GAIN 30 10 70 -40°C 40 20 -40°C 80 50 20 20 0 -10 60 90 85°C PHASE PHASE (°) 40 70 60 PHASE (°) GAIN (dB) 25°C 50 70 GAIN (dB) 70 60 PHASE (°) 85°C PHASE 80 100 PHASE (°) 100 20 VS = 5V 1k 100k 10M FREQUENCY (Hz) 10 10 VS = 16V 1k 1M 10M FREQUENCY (Hz) Figure 6. Figure 7. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 7 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com Typical Performance Characteristics (continued) Unless otherwise specified, all limits ensured for TJ = 25°C, VCM = 1/2VS and RL = 2kΩ. CMRR (VS = 5V) CMRR (VS = 16V) 120 120 VS = 5V 110 100 100 90 90 CMRR (dB) CMRR (dB) 110 80 70 80 70 60 60 50 50 40 40 30 30 10 1k 1M 10 10M 1k FREQUENCY (Hz) Figure 9. Settling Time vs. Input Step Amplitude (Output Slew and Settle Time) Settling Time vs. Capacitive Loading (Output Slew and Settle Time) 1200 RL = 2k: RL = 2k: 0.1% SETTLING TIME (nS) 0.1% SETTLING TIME(nS) 250 200 150 100 50 1000 800 600 400 200 0 0.75 1 1.25 1.5 1.75 2 0 30 40 50 60 Figure 11. Crosstalk Rejection vs. Frequency (Output to Output) Input Voltage Noise vs. Frequency 70 80 1000 Hz) 100 INPUT VOLTAGE NOISE (nV/ 90 CT REJECTION (dB) 20 Figure 10. 110 80 70 60 50 40 30 20 100 10 1 1k 100k FREQUENCY (Hz) 10M 1 10 100 1k 10k 1M FREQUENCY (Hz) Figure 12. 8 10 CAPACITIVE LOADING (pF) INPUT STEP AMPLITUDE (VPP) 10 10 10M Figure 8. 300 0 0.5 1M FREQUENCY (Hz) Figure 13. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 Typical Performance Characteristics (continued) Unless otherwise specified, all limits ensured for TJ = 25°C, VCM = 1/2VS and RL = 2kΩ. Stability vs. Capacitive Load Unity Gain (VS = 16V) Large Signal Step Response 1M VS = 12V VO = 2VPP 100k CAP LOAD (pF) AV = -1, RL = 2k: 10k UNSTABLE 1k 100 10 25% OVERSHOOT 1 -5 -4 -3 -2 -1 0 1 2 3 4 1V/DIV 5 100ns/DIV VOUT (V) Figure 14. Figure 15. Small Signal Step Response Small Signal Step Response VS = 12V VS = 12V VO = 100mVPP VO = 100mVPP AV = +1, RL = 2k: AV = -1, RL = 2k: 50mV/DIV 100ns/DIV 50mV/DIV 100ns/DIV Figure 16. Figure 17. Closed Loop Output Impedance vs. Frequency (AV = +1) ISUPPLY vs. Common Mode Voltage (VS = ±5V) 1000 4 VS = ±5V AV = +1 85°C 100 3.5 ISUPPY (mA) ZOUT (:) 10 1 25°C 3 0.1 2.5 -40°C 0.01 2 0.001 10 1k 1M 10M -7 -5 -3 -1 1 3 5 7 COMMON MODE VOLTAGE (V) FREQUENCY (Hz) Figure 18. Figure 19. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 9 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com Typical Performance Characteristics (continued) Unless otherwise specified, all limits ensured for TJ = 25°C, VCM = 1/2VS and RL = 2kΩ. VOS vs. Common Mode Voltage (VS = 16V) VOS vs. VOUT (Typical Unit), (VS = 10V) 1 1 VS = 10V 0.75 0.5 85°C 0.25 VOS (mV) VOS (mV) 0.5 -40°C 0 85°C 0 -0.25 25°C -0.5 -0.5 25°C -40°C -0.75 -1 -1 -7 -5 -3 -1 1 3 -7 -6 -5 -4 -3 -2 -1 0 1 2 7 5 COMMON MODE VOLTAGE (V) Figure 20. Figure 21. VOUT from V+ vs. ISOURCE VOUT from V− vs. ISINK 10 VOUT FROM V (V) 10 1 1 - + VOUT FROM V (V) 3 4 5 6 7 VOUT (V) 85°C 25°C 0.1 -40°C 85°C 0.1 -40°C 25°C 0.01 0.01 1 10 100 1000 1 ISOURCE (mA) 10 100 1000 ISINK (mA) Figure 22. Figure 23. ISUPPLY vs. Supply Voltage 4 85°C ISUPPLY (mA) 3.5 25°C 3 2.5 -40°C 2 4 6 8 10 12 14 16 VSUPPLY (V) Figure 24. 10 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 Application Notes CIRCUIT DESCRIPTION GENERAL & SPEC The LM6588 is a bipolar process operational amplifier. It has an exceptional output current capability of 200mA. The part has both rail to rail inputs and outputs. It has a −3dB bandwidth of 24MHz. The part has input voltage noise of 23nV/√Hz, and 2nd and 3rd harmonic distortion of −53dB and −40dB respectively. INPUT SECTION The LM6588 has rail to rail inputs and thus has an input range over which the device may be biased of V− minus 0.5V, and V+ plus 0.5V. The ultimate limit on input voltage excursion is the ESD protection diodes on the input pins. The most important consideration in Rail-to-Rail input op amps is to understand the input structure. Most Rail-to-Rail input amps use two differential input pairs to achieve this function. This is how the LM6588 works. A conventional PNP differential transistor pair provides the input gain from 0.5V below the negative rail to about one volt below the positive rail. At this point internal circuitry activates a differential NPN transistor pair that allows the part to function from 1 volt below the positive rail to 0.5V above the positive rail. The effect on the inputs pins is as if there were two different op amps connected to the inputs. This has several unique implications. • The input offset voltage will change, sometimes from positive to negative as the inputs transition between the two stages at about a volt below the positive rail. this effect is seen in the VOS vs. VCM chart in the Typical Performance Characteristics section of this datasheet. • The input bias currents can be either positive or negative. Do not expect a consistent flow in or out of the pins. • The part will have different specifications depending on whether the NPN or PNP stage is operating. • There is a little more input capacitance then a single stage input although the ESD diodes often swamp out the added base capacitance. • Since the input offset voltages can change from positive to negative the output may not be monotonic when the inputs are transitioning between the two stages and the part is in a high gain configuration. It should be remembered that swinging the inputs across the input stage transition may cause output distortion and accuracy anomalies. It is also worth noting that anytime any amps inputs are swung near the rails THD and other specs are sure to suffer. OUTPUT SECTION Current Rating The LM6588 has an output current rating, sinking or sourcing, of 200mA. The LM6588 is ideally suited to loads that require a high value of peak current but only a reduced value of average current. This condition is typical of driving the gate of a MOSFET. While the output drive rating is 200mA peak, and the output structure supports rail-to-rail operation, the attainable output current is reduced when the gain and drive conditions are such that the output voltage approaches either rail. Output Power Because of the increased output drive capability, internal heat dissipation must be held to a level that does not increase the junction temperature above its maximum rated value of 150° C. Power Requirements The LM6588 operates from a voltage supply, of V+ and ground, or from a V− and V+ split supply. Single-ended voltage range is +5V to +16V and split supply range is ±2.5V to ±8.0V. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 11 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com APPLICATION HINTS POWER SUPPLIES Sequencing Best practice design technique for operational amplifiers includes careful attention to power sequencing. Although the LM6588 is a bipolar op amp, recommended op amp turn on power sequencing of ground (or V−), followed by V+, followed by input signal should be observed. Turn off power sequence should be the reverse of the turn-on sequence. Depending on how the amp is biased the outputs may swing to the rails on power-on or power-off. Due to the high output currents and rail to rail output stage in the LM6588 the output may oscillate very slightly if the power is slowly raised between 2V and 4V The part is unconditionally stable at 5V. Quick turnoff and turn-on times will eliminate oscillation problems. PSRR and Noise Care should be taken to minimize the noise in the power supply rails. The figure of merit for an op amp’s ability to keep power supply noise out of the signal is called Power Supply Rejection Ratio (PSRR). Observe from the PSRR charts in the Typical Performance Characteristics section that the PSRR falls of dramatically as the frequency of the noise on the power supply line goes up. This is one of the reasons switching power supplies can cause problems. It should also be noticed from the charts that the negative supply pin is far more susceptible to power noise. The design engineer should determine the switching frequencies and ripple voltages of the power supplies in the system. If required, a series resistor or in the case of a high current op amp like the LM6588, a series inductor can be used to filter out the noise. Transients In addition to the ripple and noise on the power supplies there are also transient voltage changes. This can be caused by another device on the same power supply suddenly drawing current or suddenly stopping a current draw. The design engineer should insure that there are no damaging transients induced on the power supply lines when the op amp suddenly changes current delivery. LAYOUT Ground Planes Do not assume the ground (or more properly, the common or return) of the power supply is an ocean of zero impedance. The thinner the trace, the higher the resistance. Thin traces cause tiny inductances in the power lines. These can react against the large currents the LM6588 is capable of delivering to cause oscillations, instability, overshoot and distortion. A ground plane is the most effective way of insuring the ground is a uniform low impedance. If a four layer board cannot be used, consider pouring a plane on one side of a two layer board. If this cannot be done be sure to use as wide a trace as practicable and use extra decoupling capacitors to minimize the AC variations on the ground rail. Decoupling A high-speed, high-current amp like the LM6588 must have generous decoupling capacitors. They should be as close to the power pins as possible. Putting them on the back side opposite the power pins may give the tightest layout. If ground and power planes are available, the placement of the decoupling caps are not as critical. Breadboards The high currents and high frequencies the LM6588 operates at, as well as thermal considerations, require that prototyping of the design be done on a circuit board as opposed to a “Proto-Board” style breadboard. STABILITY General: High speed parts with large output current capability require special care to insure lack of oscillations. Keep the ”+” pin isolated from the output to insure stability. As noted above care should be take to insure the large output currents do not appear in the ground or ground plane and then get coupled into the “+” pin. As always, good tight layout is essential as is adequate use of decoupling capacitors on the power supplies. 12 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 Unity Gain The unity gain or voltage-follower configuration is the most subject to oscillation. If a part is stable at unity gain it is almost certain to work in other configurations. In certain applications where the part is setting a reference voltage or is being used as a buffer greater stability can be achieved by configuring the part as a gain of −1 or −2 or +2. Phase Margin The phase margin of an op amps gain-phase plot is an indication of the stability of the amp. It is desirable to have at least 45°C of phase margin to insure stability in all cases. The LM6588 has 60°C of phase margin even with it’s large output currents and Rail-to-Rail output stage, which are generally more prone to stability issues. Capacitive Load The LM6588 can withstand 30pF of capacitive load in a unity gain configuration before stability issues arise. At very large capacitances, the load capacitor will attenuate the gain like any other heavy load and the part becomes stable again. The LM6588 will be stable at 330nF and higher load capacitance. Refer to the chart in the Typical Performance Characteristics section. OUTPUT Swing vs. Current The LM6588 will get to about 25mV or 30mV of either rail when there is no load. The LM6588 can sink or source hundreds of milliamperes while remaining less then 0.5V away from the rail. It should be noted that if the outputs are driven to the rail and the part can no longer maintain the feedback loop, the internal circuitry will deliver large base currents into the huge output transistors, trying to get the outputs to get past the saturation voltage. The base currents will approach 16 milliamperes and this will appear as an increase in power supply current. Operating at this power dissipation level for extended periods will damage the part, especially in the higher thermal resistance TSSOP package. Because of this phenomenon, unused parts should not have the inputs strapped to either rail, but should have the inputs biased at the midpoint or at least a diode drop (0.6V) within the rails. Self Heating As discussed above the LM6588 is capable of significant power by virtue of its 200mA current handling capability. A TSSOP package cannot sustain these power levels for more then a brief period. TFT Display Application INTRODUCTION In today’s high-resolution TFT displays, op amps are used for the following three functions: 1. VCOM Driver 2. Gamma Buffer 3. Panel Repair Buffer All of these functions utilize op amps as non-inverting, unity-gain buffers. The VCOM Driver and Gamma Buffer are buffers that supply a well regulated DC voltage. A Panel Repair Buffer, on the other hand, provides a high frequency signal that contains part of the display’s visual image. In an effort to reduce production costs, display manufacturers use a minimum variety of different parts in their TFT displays. As a result, the same type of op amp will be used for the VCOM Driver, Gamma Buffer, and Panel Repair Buffer. To perform all these functions, such an op amp must have the following characteristics: 1. Large output current drive 2. Rail to rail input common mode range 3. Rail to rail output swing 4. Medium speed gain bandwidth and slew rate Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 13 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com The LM6588 meets these requirements. It has a rail-to-rail input and output, typical gain bandwidth and slew rate of 15MHz and 15V/μs, and it can supply up to 200mA of output current. The following sections will describe the operation of VCOM Drivers, Gamma Buffers, and Panel Repair Buffers, showing how the LM6588 is well suited for each of these functions. BRIEF OVERVIEW OF TFT DISPLAY To better understand these op amp applications, let’s first review a few basic concepts of how a TFT display operates. Figure 25 is a simplified illustration of an LCD pixel. The top and bottom plates of each pixel consist of Indium-Tin oxide (ITO), which is a transparent, electrically conductive material. ITO lies on the inner surfaces of two glass substrates that are the front and back glass panels of a TFT display. Sandwiched between the two ITO plates is an insulating material (liquid crystal) that alters the polarization of light to a lesser a greater amount, depending on how much voltage (VPIXEL) is applied across the two plates. Polarizers are placed on the outer surfaces of the two glass substrates, which in combination with the liquid crystal create a variable light filter that modulates light transmitted from the back to the front of a display. A pixel’s bottom plate lies on the backside of a display where a light source is applied, and the top plate lies on the front, facing the viewer. On a Twisted Neumatic (TN) display, which is typical of most TFT displays, a pixel transmits the greatest amount of light when VPIXEL is less ±0.5V, and it becomes less transparent as this voltage increases with either a positive or negative polarity. In short, an LCD pixel can be thought of as a capacitor, through which, a controlled amount of light is transmitted by varying VPIXEL. TRANSMITTED LIGHT POLARIZER GLASS SUBSTRATE LIQUID CRYSTAL MATERIAL GLASS SUBSTRATE TOP ITO PLATE BOTTOM ITO PLATE VPIXEL ± POLARITY POLARIZER LIGHT SOURCE Figure 25. Individual LCD Pixel 14 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 ROW DRIVERS COLUMN DRIVERS CSTRAY CSTRAY CSTRAY VCOM VCOM VCOM PIXEL PIXEL PIXEL APPROX VDD/2 + - TFT-LCD PANEL VCOM VCOM DRIVER Figure 26. TFT Display Figure 26 is a simplified block diagram of a TFT display, showing how individual pixels are connected to the row, column, and VCOM lines. Each pixel is represented by capacitor with an NMOS transistor connected to its top plate. Pixels in a TFT panel are arranged in rows and columns. Row lines are connected to the NMOS gates, and column lines to the NMOS sources. The back plate of every pixel is connected to a common voltage called VCOM. Pixel brightness is controlled by voltage applied to the top plates, and the Column Drivers supply this voltage via the column lines. Column Drivers ‘write’ this voltage to the pixels one row at a time, and this is accomplished by having the Row Drivers select an individual row of pixels when their voltage levels are transmitted by the Column Drivers. The Row Drivers sequentially apply a large positive pulse (typically 25V to 35V) to each row line. This turns-on NMOS transistors connected to an individual row, allowing voltages from the column lines to be transmitted to the pixels. VCOM DRIVER The VCOM driver supplies a common voltage (VCOM) to all the pixels in a TFT panel. VCOM is a constant DC voltage that lies in the middle of the column drivers’ output voltage range. As a result, when the column drivers write to a row of pixels, they apply voltages that are either positive or negative with respect to VCOM. In fact, the polarity of a pixel is reversed each time its row is selected. This allows the column drivers to apply an alternating voltage to the pixels rather than a DC signal, which can ‘burn’ a pattern into an LCD display. When column drivers write to the pixels, current pulses are injected onto the VCOM line. These pulses result from charging stray capacitance between VCOM and the column lines (see Figure 26), which ranges typically from 16pF to 33pF per column. Pixel capacitance contributes very little to these pulses because only one pixel at a time is connected to a column, and the capacitance of a single pixel is on the order of only 0.5pF. Each column line has a significant amount of series resistance (typically 2kΩ to 40kΩ), so the stray capacitance is distributed along the entire length of a column. This can be modeled by the multi-segment RC network shown in Figure 27. The total capacitance between VCOM and the column lines can range from 25nF to 100nF, and charging this capacitance can result in positive or negative current pulses of 100mA, or more. In addition, a similar distributed capacitance of approximately the same value exists between VCOM and the row lines. Therefore, the VCOM driver’s load is the sum of these distributed RC networks with a total capacitance of 50nF to 200nF, and this load can modeled like the circuit in Figure 27. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 15 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com R R C C R R R VCOM C C C COLUMN LINE Figure 27. Model of Impedance between VCOM and Column Lines A VCOM driver is essentially a voltage regulator that can source and sink current into a large capacitive load. To simplify the analysis of this driver, the distributed RC network of Figure 27 has been reduced to a single RC load in Figure 28. This load places a large capacitance on the VCOM driver output, resulting in an additional pole in the op amp’s feedback loop. However, the op amp remains stable because CLOAD and RESR create a zero that cancels the effect of this pole. The range of CLOAD is 50nF to 200nF and RESR is 20Ω to 100Ω, so this zero will have a frequency in the range of 8KHz to 160KHz, which is much lower than the gain bandwidth of most op amps. As a result, the VCOM load adds very little phase lag when op amp loop gain is unity, and this allows the VCOM Driver to remain stable. This was verified by measuring the small-signal bandwidth of the LM6588 with the RC load of Figure 28. When driving an RC load of 50nF and 20Ω, the LM6588 has a unity gain frequency of 6.12MHz with 41.5°C of phase margin. If the load capacitor is increased to 200nF and the resistance remains 20Ω, the unity gain frequency is virtually unchanged: 6.05MHz with 42.9°C of phase margin. VCOM LOAD VCOM DRIVER APPROX VDD/2 + - VCOM CLOAD 50 - 200nF RESR 20 - 100: Figure 28. VCOM Driver with Simplified Load A VCOM Driver’s large-signal response time is determined by the op amp’s maximum output current, not by its slew rate. This is easily shown by calculating how much output current is required to slew a 50nF load capacitance at the LM6588 slew rate of 14V/μs: IOUT = 14V/μs x 50nF = 700mA (1) 700mA exceeds the maximum current specification for the LM6588 and almost all other op amps, confirming that a VCOM driver’s speed is limited by its peak output current. In order to minimize VCOM transients, the op amp used as a VCOM Driver must supply large values of output current. 16 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 RF2 300: RF1 3k: VCOM VCOM LOAD +6.5V - RS 10: RL1 10: RL2 10: RL3 10: C2 10nF C3 10nF C4 10nF + -6.5V IOUT C1 10nF VSW 5V 0V Figure 29. VCOM Driver Test Circuit (2V/DIV) (5V/DIV) Figure 29 is a common test circuit used for measuring VCOM driver response time. The RC network of RL1 to RL3 and C1 to C4 models the distributed RC load of a VCOM line. This RC network is a gross simplification of what the actual impedance is on a TFT panel. However, it does provide a useful test for measuring the op amp’s transient response when driving a large capacitive load. A low impedance MOSFET driver applies a 5V square wave to VSW, generating large current pulses in the RC network. Scope photos from this circuit are shown in Figure 30 and Figure 31. Figure 30 shows the test circuit generates positive and negative voltage spikes with an amplitude of ±3.2V at the VCOM node, and both transients settle-out in approximately 2μs. As mentioned before, the speed at which these transients settle-out is a function of the op amp’s peak output current. The IOUT trace in Figure 31 shows that the LM6588 can sink and source peak currents of −200mA and 200mA. This ability to supply large values of output current makes the LM6588 extremely well suited for VCOM Driver applications. VSW VCOM 2PSec/DIV Figure 30. VSW and VCOM Waveforms from VCOM Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 17 LM6588 www.ti.com (5 V/DIV) SNOSA77D – MAY 2003 – REVISED MARCH 2013 (200 mA/DIV) VSW ICOM 2 PSec/DIV Figure 31. VSW and IOUT Waveforms from VCOM Test Circuit GAMMA BUFFER Illumination in a TFT display, also referred to as grayscale, is set by a series of discrete voltage levels that are applied to each LCD pixel. These voltage levels are generated by resistive DAC networks that reside inside each of the column driver ICs. For example, a column driver with 64 Grayscale levels has a two 6 bit resistive DACs. Typically, the two DACs will have their 64 resistors grouped into four segments, as shown in Figure 32. Each of these segments is connected to external voltage lines, VGMA1 to VGMA10, which are the Gamma Levels. VGMA1 to VGMA5 set grayscale voltage levels that are positive with respect to VCOM (high polarity gamma levels). VGMA6 to VGMA10 set grayscale voltages negative with respect to VCOM (low polarity gamma levels). HIGH POLARITY GAMMA LEVEL INPUTS LOW POLARITY GAMMA LEVEL INPUTS VGMA1 VGMA9 VGMA3 VGMA5 VGMA7 VGMA6 VGMA10 VGMA2 VGMA4 VGMA8 RESISTIVE DAC RESISTIVE DAC CMOS TRANSMISSION GATES COLUMN DRIVER BUFFERS CMOS TRANSMISSION GATES COLUMN DRIVER BUFFERS Figure 32. Simplified Schematic of Column Driver IC 18 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 Figure 33 shows how column drivers in a TFT display are connected to the gamma levels. VGMA1, VGMA5, VGMA6, and VGMA10 are driven by the Gamma Buffers. These buffers serve as low impedance voltage sources that generate the display’s gamma levels. The Gamma Buffers’ outputs are set by a simple resistive ladder, as shown in Figure 33. Note that VGMA2 to VGMA4 and VGMA7 to VGMA9 are usually connected to the column drivers even though they are not driven by external buffers. Doing so, forces the gamma levels in all the column drivers to be identical, minimizing grayscale mismatch between column drivers. Referring again to Figure 33, the resistive load of a column driver DAC (i.e. resistance between GMA1 to GMA5) is typically 10kΩ to 15kΩ. On a typical display such as XGA, there can be up to 10 column drivers, so the total resistive load on a Gamma Buffer output can be as low as 1kΩ. The voltage between VGMA1 and VGMA5 can range from 3V to 6V, depending on the type of TFT panel. Therefore, maximum load current supplied by a Gamma Buffer is approximately 6V/1kΩ = 6mA, which is a relatively light load for most op amps. In many displays, VGMA1 can be less than 500mV below VDD, and VGMA10 can be less than 500mV above ground. Under these conditions, an op amp used for the Gamma Buffer must have rail-to-rail inputs and outputs, like the LM6588. VDD VGMA1 VGMA2 VGMA3 VGMA4 VGMA5 + - + - + - + - VGMA6 VGMA7 VGMA8 VGMA9 VGMA10 GAMMA BUFFERS COLUMN DRIVERS COLUMN DRIVERS TFT-LCD PANEL Figure 33. Basic Gamma Buffer Configuration Another important specification for Gamma Buffers is small signal bandwidth and slew rate. When column drivers select which voltage levels are written to a row of pixels, their internal DACs inject current spikes into the Gamma Lines. This generates voltage transients at the Gamma Buffer outputs, and they should settle-out in less than 1μs to insure a steady output voltage from the column drivers. Typically, these transients have a maximum amplitude of 2V, so a gamma buffer must have sufficient bandwidth and slew rate to recover from a 2V transient in 1μs or less. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 19 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com VOUT VF t 0 TPD TSR TSET Figure 34. Large Signal Transient Response of an Operational Amplifier Figure 34 illustrates how an op amp responds to a large-signal transient. When such a transient occurs at t = 0, the output does not start changing until TPD, which is the op amp’s propagation delay time (typically 20ns for the LM6588). The output then changes at the op amp’s slew rate from t = TPD to TSR. From t = TSR to TSET, the output settles to its final value (VF) at a speed determined by the op amp’s small-signal frequency response. Although propagation delay and slew limited response time (t = 0 to TSR) can be calculated from data sheet specifications, the small signal settling time (TSR to TSET) cannot. This is because an op amp’s gain vs. frequency has multiple poles, and as a result, small-signal settling time can not be calculated as a simple function of the op amp’s gain bandwidth. Therefore, the only accurate method for determining op amp settling time is to measure it directly. 2V 0 OR 0 AMPLIFIER UNDER TEST -2V +6.5V HP 8082 PULSE GENERATOR + 50: -6.5V RLOAD 1k: TEK 7633 STORAGE SCOPE + TEK 7S14 SAMPLING INPUT Figure 35. Gamma Buffer Settling Time Test Circuit The test circuit in Figure 35 was used to measure LM6588 settling time for a 2V pulse and 1kΩ load, which represents the maximum transient amplitude and output load for a gamma buffer. With this test system, the LM6588 settled to within ±30mV of 2V pulse in approximately 170ns. Settling time for a 0 to –2V pulse was slightly less, 150ns. These values are much smaller than the desired response time of 1μs, so the LM6588 has sufficient bandwidth and slew rate for regulating gamma line transients. PANEL REPAIR BUFFER It is not uncommon for a TFT panel to be manufactured with an open in one or two of its column or row lines. In order to repair these opens, TFT panels have uncommitted repair lines that run along their periphery. When an open line is identified during a panel’s final assembly, a repair line re-routes its signal past the open. Figure 36 illustrates how a column is repaired. The column driver’s output is sent to the other end of an open column via a repair line, and the repair line is driven by a panel repair buffer. When a column or row line is repaired, the 20 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 LM6588 www.ti.com SNOSA77D – MAY 2003 – REVISED MARCH 2013 capacitance on that line increases substantially. For instance, a column typically has 50pF to 100pF of line capacitance, but a repaired column can have up to 200pF. Column drivers are not designed to drive this extra capacitance, so a panel repair buffer provides additional output current to the repaired column line. Note that there is typically a 20Ω to 100Ω resistor in series with the buffer output. This resistor isolates the output from the 200pF of capacitance on a repaired column line, ensuring that the buffer remains stable. A pole is created by this resistor and capacitance, but its frequency will be in the range of 8MHz to 40MHz, so it will have only a minor effect on the buffer’s transient response time. Panel repair buffers transmit a column driver signal, and as mentioned in the gamma buffer section, this signal is set by the gamma levels. It was also mentioned that many displays have upper and lower gamma levels that are within 500mV of the supply rails. Therefore, op amps used as panel repair buffers should have rail-to-rail input and stages. Otherwise, they may clip the column driver signal. The signal from a panel repair buffer is stored by a pixel when the pixel’s row is selected. In high-resolution displays, each row is selected for as little as 11μs. To insure that a pixel has adequate time to settle-out during this brief period, a panel repair buffer should settle to within 1% of its final value approximately 1μs after a row is selected. This is hardest to achieve when transmitting a column line’s maximum voltage swing, which is the difference between the upper and lower gamma levels (i.e. voltage between VGMA1 and VGMA10). For a LM6588, the most demanding application occurs in displays that operate from a 16V supply. In these displays, voltage difference between the top and bottom gamma levels can be as large as 15V, so the LM6588 needs to transmit a ±15V pulse and settle to within 60mV of its final value in approximately 1μs (60mV is approximately 1% of the dynamic range of the high or low polarity gamma levels). LM6588 settling times for 15V and –15V pulses were measured in a test circuit similar to the one in Figure 35. V+ and V− were set to 15.5V and –0.5V, respectively, when measuring settling time for a 0V to 15V pulse. Likewise, V+ and V− were set to 0.5V and –15.5V when measuring settling time for a 0V to –15V pulse. In both cases, the LM6588 output was connected to a series RC load of 51Ω and 200pF. When tested this way, the LM6588 settled to within 60mV of 15V or –15V in approximately 1.1μs. These observed values are very close to the desired 1μs specification, demonstrating that the LM6588 has the bandwidth and slew rate required for repair buffers in high-resolution TFT displays. COLUMN DRIVER PANEL REPAIR BUFFER 20 TO 100: + - TFT-LCD PANEL OPEN COLUMN LINE PANEL REPAIR LINE Figure 36. Panel Repair Buffer SUMMARY This application note provided a basic explanation of how op amps are used in TFT displays, and it also presented the specifications required for these op amps. There are three major op amp applications in a display: VCOM Driver, Gamma Buffer, and Panel Repair Buffer, and the LM6588 can be used for all of them. As a VCOM Driver, the LM6588 can supply large values of output current to regulate VCOM load transients. It has rail-to-rail input common-mode range and output swing required for gamma buffers and panel repair buffers. It also has the necessary gain bandwidth and slew-rate for regulating gamma levels and driving column repair lines. All these features make the LM6588 very well suited for use in TFT displays. Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 21 LM6588 SNOSA77D – MAY 2003 – REVISED MARCH 2013 www.ti.com REVISION HISTORY Changes from Revision C (March 2013) to Revision D • 22 Page Changed layout of National Data Sheet to TI format .......................................................................................................... 21 Submit Documentation Feedback Copyright © 2003–2013, Texas Instruments Incorporated Product Folder Links: LM6588 PACKAGE OPTION ADDENDUM www.ti.com 10-Dec-2020 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan (2) Lead finish/ Ball material MSL Peak Temp Op Temp (°C) Device Marking (3) (4/5) (6) LM6588MA/NOPB NRND SOIC D 14 55 RoHS & Green SN Level-1-260C-UNLIM -40 to 85 LM6588MA LM6588MAX/NOPB NRND SOIC D 14 2500 RoHS & Green SN Level-1-260C-UNLIM -40 to 85 LM6588MA LM6588MT/NOPB NRND TSSOP PW 14 94 RoHS & Green SN Level-1-260C-UNLIM -40 to 85 LM658 8MT LM6588MTX/NOPB NRND TSSOP PW 14 2500 RoHS & Green SN Level-1-260C-UNLIM -40 to 85 LM658 8MT (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of