FEATURES TYPICAL APPLICATIO. LT6550/LT V Triple and Quad Video Amplifiers DESCRIPTIO APPLICATIO S

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FEATRES Single Supply Operation from V to.v Small (mm mm) MSOP -Lead Package Internal Resistors for a Gain of Two V/µs Slew Rate MHz db Bandwidth MHz Flat to.

1 FEATRES Single Supply Operation from V to.v Small (mm mm) MSOP -Lead Package Internal Resistors for a Gain of Two V/µs Slew Rate MHz db Bandwidth MHz Flat to.db % Settling Time: ns Input Common Mode Range Includes Ground Rail-to-Rail Output High Output Drive: ma Operating Temperature Range: C to C -Bit RGB APPLICATIO S Automotive Displays LCD and CRT Compatible RGB Amplifiers Coaxial Cable Drivers Low Voltage High Speed Signal Processing Set Top Boxes, LTC and LT are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. DESCRIPTIO LT/LT.V Triple and Quad Video Amplifiers The LT /LT are.v triple and quad high speed video amplifiers. These voltage feedback amplifiers drive double terminated Ω or cables and are configured for a fixed gain of, eliminating six or eight external gain setting resistors. The LT/LT feature MHz db bandwidth, high slew rates and fast settling, making them ideal for RGB video processing. The LT quad is designed for single supply operation and the LT triple can be used on either single or split supplies. On a single.v supply, the input voltage range extends from ground to.v and the output swings to within mv of the supply voltage while driving a Ω load. These features, combined with the ability to accept RGB video signals without the need for AC coupling or level shifting of the incoming signals, make the LT/ LT an ideal choice for low voltage video applications. Both the LT and LT are available in the small -Pin MSOP package and utilize a flow-thru pin out. The small footprint results in a compact high performance video amplifier solution. TYPICAL APPLICATIO.V Single Supply LT RGB Plus SYNC Cable Driver LT R IN.V R OT G IN Output Step Response V OT B IN G OT SYNC IN B OT SYNC OT V IN V V S =.V V IN =.V TO.V f = MHz / TAb V TAa fa

2 LT/LT ABSOLTE AXI RATI GS (Note ) W W W Total Supply Voltage LT (V CC TO V EE )....V LT (V CC TO )....V Input Current (Note )... ±ma Output Short-Circuit Duration (Note )... Indefinite Operating Temperature Range... C to C Specified Temperature Range (Note ) LTC/LTC... C to C LTI/LTI... C to C Maximum Junction Temperature... C Storage Temperature Range... C to C Lead Temperature (Soldering, sec)... C PACKAGE/ORDER I FOR ATIO W IN IN IN V EE ORDER PART NMBER LTCMS LTIMS TOP VIEW X X X MS PACKAGE -LEAD PLASTIC MSOP T JMAX = C, θ JA = C/W (Note ) V CC OT OT OT N/C MS PART MARKING LTB LTC Consult LTC Marketing for parts specified with wider operating temperature ranges. IN IN IN IN ORDER PART NMBER LTCMS LTIMS Order Options Tape and Reel: Add #TR Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF Lead Free Part Marking: TOP VIEW X X X X MS PACKAGE -LEAD PLASTIC MSOP T JMAX = C, θ JA = C/W (Note ) V CC OT OT OT OT MS PART MARKING LTC LTC.V ELECTRICAL CHARACTERISTICS The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C. V CC =.V, V = V; V IN =.V LT (Pins,,); LT (Pins,,,). V EE = V LT (Pin ), unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS DC Output Accuracy No Load, V OT Ideal =.V mv Output Voltage Matching Between Any Two Outputs mv Input Current Any Input µa Input Impedance, V IN / I IN V IN = V to V kω Input Noise Voltage Density f = khz (Note ) nv/ Hz Input Noise Current Density f = khz (Note ) pa/ Hz Voltage Gain (Note ).V V IN.V No Load.. V/V R L = Ω.. V/V R L =,.V V IN.V.. V/V Output Voltage Swing Low V IN =.V No Load mv I SINK = ma mv I SINK = ma mv fa

3 .V ELECTRICAL CHARACTERISTICS LT/LT The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C. V CC =.V, V = V; V IN =.V LT (Pins,,); LT (Pins,,,). V EE = V LT (Pin ), unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS Output Voltage Swing High V IN =.V No Load.. V R L = Ω.. V R L =.. V PSRR V CC = V to V, V IN =.V db Minimum Supply Voltage (Note ) V Output Short-Circuit Current V IN = V, V OT = V ma ma Supply Current per Amplifier (Note ). ma ma Slew Rate (Note ) R L = Ω, V OT =.V to.v V/µs Measured from V to V V/µs Small Signal db Bandwidth R L = Ω MHz Gain Flatness Less than.db MHz Gain Matching Any One Channel to Any Other Channel. db Settling Time to % R L = Ω, V OT = V to.v ns Settling Time to % R L = Ω, V OT = V to.v ns % Overshoot V OT = V to.v, R L = Ω % Differential Gain R L = Ω, Black Level =.V at Device Output. % Differential Phase R L = Ω, Black Level =.V at Device Output. Deg Channel Separation Measured at MHz db V ELECTRICAL CHARACTERISTICS The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C. V CC = V, V = V; V IN =.V LT (Pins,,); LT (Pins,,,). V EE = V LT (Pin ), unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS Output Accuracy No Load, V OT Ideal =.V mv Output Voltage Matching Between Any Two Outputs mv Input Current µa Input Impedance, V IN / I IN V IN = V to V kω Input Noise Voltage Density f = khz (Note ) nv/ Hz Input Noise Current Density f = khz (Note ) pa/ Hz Voltage Gain (Note ).V V IN.V No Load.. V/V R L = Ω.. V/V R L =,.V V IN.V, C T A C (Only).. V/V Output Voltage Swing Low V IN =.V No Load mv I SINK = ma mv I SINK = ma mv Output Voltage Swing High V IN =.V No Load.. V R L = Ω.. V R L =, C T A C (Only).. V fa

4 LT/LT V ELECTRICAL CHARACTERISTICS The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C. V CC = V, V = V; V IN =.V LT (Pins,,); LT (Pins,,,). V EE = V LT (Pin ), unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS PSRR V CC = V to V, V IN =.V db Minimum Supply Voltage (Note ) V Output Short-Circuit Current V IN = V, V OT = V ma C T A C ma C T A C ma Supply Current per Amplifier (Note ).. ma. ma Slew Rate R L = Ω, V OT =.V to.v, V/µs Measured from V to V V/µs Small Signal db Bandwidth R L = Ω MHz Gain Flatness Less than.db MHz Gain Matching Any One Channel to Any Other Channel. db Settling Time to % R L = Ω, V OT = V to.v ns Settling Time to % R L = Ω, V OT = V to.v ns % Overshoot V OT = V to.v, R L = Ω % Differential Gain R L = Ω, Black Level = V at Device Output. % Differential Phase R L = Ω, Black Level = V at Device Output. Deg Channel Separation Measured at MHz db ±V ELECTRICAL CHARACTERISTICS (LT Only) The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C., V IN = V (Pins,,) V = V (Pin ) unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS Output Offset mv Output Voltage Matching Between Any Two Outputs mv Input Current µa Input Impedance, V IN / I IN V IN = V to V kω Input Noise Voltage Density f = khz (Note ) nv/ Hz Input Noise Current Density f = khz (Note ) pa/ Hz Voltage Gain.V V IN.V No Load.. V/V R L = Ω.. V/V R L =, V V IN V.. V/V Output Voltage Swing V IN = ±.V No Load ±. ±. V R L = Ω ±. ±. V R L =, C T A C (Only) ±. ±. V PSRR V S = ±.V to ±V, db Output Short-Circuit Current V O = V ma C T A C ma C T A C ma fa

5 ±V ELECTRICAL CHARACTERISTICS LT/LT (LT Only) The denotes the specifications which apply over the specified temperature range, otherwise specifications are at T A = C., V IN = V (Pins,,) V = V (Pin ) unless otherwise noted. PARAMETER CONDITIONS MIN TYP MAX NITS Supply Current per Amplifier.. ma ma Slew Rate R L = Ω, V OT = V to V, V/µs Measured from V to V V/µs Small Signal db Bandwidth R L = Ω MHz Gain Flatness Less than.db MHz Gain Matching Any One Channel to Any Other Channel. db Settling Time to % R L = Ω, V OT = V to.v ns Settling Time to % R L = Ω, V OT = V to.v ns % Overshoot V OT = V to.v, R L = Ω % Differential Gain R L = Ω, Black Level = V at Device Output. % Differential Phase R L = Ω, Black Level = V at Device Output. Deg Channel Separation Measured at MHz db Note : Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note : A heat sink may be required to keep the junction temperature below absolute maximum. This depends on the power supply voltage and how many amplifiers are shorted. Note : The LTC/LTC are guaranteed to meet specified performance from C to C and are designed, characterized and expected to meet specified performance from C to C but are not tested or QA sampled at these temperatures. The LTI/LTI are guaranteed to meet specified performance from C to C. Note : Thermal resistance varies depending upon the amount of PC board metal attached to Pin of the device. θ JA is specified for a mm test board covered with oz copper on both sides. Note : Gain is measured by changing the input voltage, and dividing the change in output voltage by the change in input voltage. Note : Minimum supply voltage is guaranteed by the PSRR test. Note : The supply current specification includes additional output current through the internal feedback and gain resistor. Note : Guaranteed by correlation to slew rate at V and ±V. Note : The inputs are protected from ESD with diodes to the supplies. Note : Noise is input referred, including internal gain resistors. V/.V TYPICAL PERFOR A CE CHARACTERISTICS W V EE (Pin ) = V (LT), (Pin ) = V (LT) Supply Current Per Amplifier vs Supply Voltage Output Voltage vs Input Voltage Input Bias Current vs Temperature SPPLY CRRENT (ma) V IN =.V R L = = V T A = C T A = C T A = C VOT (V) V S =.V, V R L = Ω T A = C T A = C T A = C INPT BIAS (µa) V S = V, V V OT =.V V CC (V) V IN (V) TEMPERATRE ( C) / G / G / G fa

6 LT/LT V/.V TYPICAL PERFOR A CE CHARACTERISTICS INPT BIAS CRRENT (µa) Input Bias Current vs Input Voltage V S =.V, V T A = C T A = C T A = C INPT BIAS CRRENT (µa) W V EE (Pin ) = V (LT), (Pin ) = V (LT) Input Bias Current vs Input Voltage V S = V, V T A = C T A = C T A = C OTPT SATRATION VOLTAGE (V). Output Saturation Voltage vs Load Current (Output High) V S = V, V V IN =.V T A = C T A = C T A = C INPT VOLTAGE (V).... INPT VOLTAGE (V).... SORCING LD CRRENT (ma) / G / G / G OTPT SATRATION VOLTAGE (V)... Output Saturation Voltage vs Load Current (Output Low) V S = V, V V IN =.V T A = C T A = C T A = C. SINKING LD CRRENT (ma) OTPT SHORT-CIRCIT CRRENT (ma) Output Short-Circuit Current vs Temperature V IN = V V S = V, V V S =.V, V TEMPERATRE ( C) GAIN (db) Gain and Phase vs Frequency V S =.V, V V OT =.V DC R L = Ω GAIN k k PHASE M M M M PHASE (DEG) / G / G / GO GAIN (db)..... Gain Flatness vs Frequency V S =.V, V V OT =.V DC R L = Ω BANDWIDTH (MHz) db,.db Bandwidth vs Temperature V OT =.V DC R L = Ω V, V, db.v, V, db V, V,.dB.V, V,.dB db BANDWIDTH (MHz) db Bandwidth vs V CC V OT =.V DC = V R L = Ω. k k M M M TEMPERATRE ( C) V CC (V) / G / G / G fa

7 V/.V TYPICAL PERFOR A CE CHARACTERISTICS GAIN (db) Frequency Response with Capacitive Loads k k V S = V, V V OT =.V DC R L = Ω C L = pf C L = pf C L = pf M M C L = pf M M / G OVERSHOOT (%) W V EE (Pin ) = V (LT), (Pin ) = V (LT) Capacitive Load Handling, Overshoot vs Capacitive Load V S = V, V R L = OPEN R L = Ω CAPACITIVE LD (pf) / G SLEW RATE (V/µs) LT/LT Slew Rate vs Temperature V, V, RISING V, V, FALLING.V, V, RISING.V, V, FALLING R L = Ω TEMPERATRE ( C) / G POWER SPPLY REJECTION RATIO (db) Power Supply Rejection Ratio vs Frequency Output Impedance vs Frequency Channel Separation vs Frequency PSSR V S = V, V V OT =.V DC R L = Ω k k M M M M / G OTPT IMPEDANCE (Ω) V S = V, V V OT =.V DC. k k M M M / G GAIN(dB) V S = V, V R L = Ω ANY CHANNEL PAIR k k M M M M / G Gain Matching vs Frequency nd and rd Harmonic Distortion vs Frequency Small Signal Response. V S =.V, V V O = V P-P (.V TO.V) R L = Ω GAIN MATCHING(dB)... V S =.V, V V OT =.V DC, ANY CHANNEL PAIR. k k M M M M DISTORTION (dbc) k ND RD M M C L = pf V S = V, V V OT =.V DC R L = Ω / G / G / G fa

8 LT/LT V/.V TYPICAL PERFOR A CE CHARACTERISTICS W V EE (Pin ) = V (LT), (Pin ) = V (LT) Large Signal Response C L = pf V S = V, V V OT =.V TO.V R L = Ω / G ±V TYPICAL PERFOR A CE CHARACTERISTICS V (Pin ) = V SPPLY CRRENT (ma) Supply Current vs Total Supply Voltage W V OT = V V IN = V T A = C T A = C T A = C T A = C T A = C T A = C INPT BIAS CRRENT (µa) Input Bias Current vs Input Voltage (LT Only) OTPT OFFSET VOLTAGE (mv) Output Offset Voltage vs Temperature of Three Typical nits ± ± ± ± ± ± TOTAL SPPLY VOLTAGE (V) INPT VOLTAGE (V) TEMPERATRE ( C) / G / G / G OTPT VOLTAGE MATCHING (mv) Output Voltage Matching vs Temperature of Three Typical Parts V IN = V ANY CHANNEL PAIR TEMPERATRE ( C) OTPT SHORT-CIRCIT CRRENT (ma) Output Short-Circuit Current vs Temperature V IN = ±V SINKING SORCING TEMPERATRE ( C) GAIN(dB) Gain and Phase vs Frequency PHASE GAIN V OT = V DC R L = Ω k k M M M M PHASE (DEG) / G / G / G fa

LT/LT ±V TYPICAL PERFOR A CE CHARACTERISTICS V (Pin ) = V W (LT Only) Gain Flatness vs Frequency Gain Matching vs Frequency Frequency Response with Capacitive Loads.. V OT = V DC R L = Ω.

9 LT/LT ±V TYPICAL PERFOR A CE CHARACTERISTICS V (Pin ) = V W (LT Only) Gain Flatness vs Frequency Gain Matching vs Frequency Frequency Response with Capacitive Loads.. V OT = V DC R L = Ω. V OT = V DC R L = Ω C L = pf GAIN (db).... k k M M M GAIN MATCHING(dB)... ANY CHANNEL PAIR. k k M M M M GAIN (db) MM k k C L = pf C L = pf C L = pf M M M M / G / G / G SLEW RATE (/V µs) Slew Rate R L = Ω RISING FALLING TEMPERATRE ( C) / G POWER SPPLY REJECTION RATIO (db) Power Supply Rejection Ratio vs Frequency PSRR V OT = V DC R L = Ω PSRR k k M M M M / G OTPT IMPEDANCE (Ω) Output Impedance vs Frequency V OT = V DC. k k M M M / G Channel Separation vs Frequency nd and rd Harmonic Distortion vs Frequency Large Signal Response R L = Ω ANY CHANNEL PAIR V O = V P-P R L = Ω GAIN (db) DISTORTION (dbc) ND RD V k k M M M M k M M C L = pf R L = Ω / G / G / G fa

10 LT/LT BLOCK DIAGRA S W LT Block Diagram LT Block Diagram IN V CC IN V CC IN OT IN OT IN OT IN OT OT IN OT V EE N/C OT BD BD fa

11 LT/LT APPLICATIO S I FOR Amplifier Characteristics ATIO W Figure shows a simplified schematic of one channel of the LT quad. Resistors RF and RG provide an internal gain of. (The LT triple is a slight variation with the gain setting resistor, RG, connected to a separate ground pin). The input stage consists of transistors Q to Q and resistor R. This topology allows for high slew rates at low supply voltages. There are back-to-back series diodes, D to D, across the and inputs of each amplifier to limit the differential input voltage to ±.V. R IN limits the current through these diodes if the input differential voltage exceeds ±.V. The input stage drives the degeneration resistors of PNP and NPN current mirrors, Q to Q, that convert the differential signals into a single-ended output. The complementary drive generator supplies current to the output transistors that swing from rail-to-rail. Input Voltage Range The input voltage range is V EE to (V CC.V) over temperature. If the device is operated on a single V supply the maximum input is (V.V) or.v, and the internal gain of two will set the output voltage to.v. Increasing the input beyond.v will force the device out of its linear range, no longer a gain of, and the output will not increase beyond.v. At a higher supply voltage, i.e. V, the maximum input voltage is V.V or.v. However, due to the internal gain of, the output will clip with a lower input voltage. For linear unclipped operation the minimum input voltage is (V OT Min)/ and the maximum input voltage is (V OT Max)/ or (V CC.V), whichever is less. ESD The LT/LT have reverse-biased ESD protection diodes on all inputs and outputs as shown in Figure. If these pins are forced beyond either supply, unlimited current will flow through these diodes. If the current is limited to ma or less, no damage to the device will occur. RF I I I R R V Q DESD IN DESD V R IN Ω D D Q Q Q Q R Q Q Q Q Q Q CM COMPLEMENTARY DRIVE GENERATOR V DESD OT DESD D D Q Q Q RG I R R F Figure. LT Simplified Schematic fa

12 LT/LT APPLICATIO S I FOR ATIO W Power Dissipation The LT/LT, enhanced θ JA MS package, has Pin (V EE for the LT and for the LT) fused to the lead frame. This thermal connection increases the efficiency of the PC board as a heat sink. The PCB material can be very effective at transmitting heat between the pad area attached to Pin and a ground or power plane layer. Copper board stiffeners and plated through holes can also be used to spread the heat generated by the device. Table lists the thermal resistance for several different board sizes and copper areas. All measurements were taken on / FR- board with oz copper. This data can be used as a rough guideline in estimating thermal resistance. The thermal resistance for each application will be affected by thermal interactions with other components as well as board size and shape. Table. Fused -Lead MSOP Package COPPER AREA TOPSIDE* BACKSIDE BRD AREA THERMAL RESISTANCE (mm) (mm) (mm) (JNTION-TO-AMBIENT) C/W C/W C/W C/W C/W *Device is mounted on topside. The dissipation for the amplifiers is: P D = (ma)(v) (.V) / = mw The total package power dissipation is mw. When a sq mm PC board with sq mm of oz copper on top and bottom is used, the thermal resistance is C/W. The junction temperature (T J ) is: T J = (mw)( C/W) C = C The maximum junction temperature for the LT is C so the heat sinking capability of the board is adequate for the application..v LT V As an example, calculate the junction temperature for the circuit in Figure assuming an C ambient temperature. The device dissipation can be found by measuring the supply current, calculating the total dissipation and then subtracting the dissipation in the load. F Figure. Calculating Junction Temperature fa

13 LT/LT TYPICAL APPLICATIO S Video Splitter LMINANCE µf k k LT V CC = V LMINANCE OT CHROMA V CC = V µf k k CHROMA OT LMINANCE OT S-VIDEO CONNECTOR OT CHROMA OT S-VIDEO CONNECTOR TA OT fa

14 LT/LT TYPICAL APPLICATIO Consumer products require generation of YP B P R luminance/chrominance component signals, often from RGB source content. The YP B P R format has a luminance signal and two weighted color difference signals at baseband. Even with their fixed internal gain resistors, two LTs connected as shown easily implement the required conversion matrix equations. The Y channel is a weighted average of the X amplified RGB signals and with the feedback connection of the Y channel output in the second LT back to the gain-resistor common pin, an implicit Y subtraction is performed for the chroma channels and the desired unity gain is produced for the Y-channel. The necessary scaling of the color-difference signals is performed passively by their respective output termination resistor networks. Since this circuit naturally produces bipolar chroma signals (±.V at the cable load) regardless of RGB offset, the simplest implementation is to power the circuit with ±.V split supplies. With an available output swing of about.v for this supply configuration, the circuit handles video with composite syncs and/ or various offsets without difficulty. RGB to YP B P R Component-Video Conversion.V.V LT LT R Ω Ω Ω P R G Ω Y B Ω Ω Ω P B.V.V / TAO Y =.R.G.B P B =.(B Y) P R =.(R Y) f db MHz fa

15 LT/LT PACKAGE DESCRIPTIO MS Package -Lead Plastic MSOP (Reference LTC DWG # --). ±. (. ±.). (.) MIN.. (..). ±. (. ±.) TYP. (.) BSC RECOMMENDED SOLDER PAD LAYOT. ±. (. ±.) (NOTE ). ±. (. ±.) REF GAGE PLANE. (.). (.) DETAIL A DETAIL A NOTE:. DIMENSIONS IN MILLIMETER/(INCH). DRAWING NOT TO SCALE TYP. ±. (. ±.) SEATING PLANE. ±. (. ±.). (.) MAX.. (..) TYP. (.) BSC. DIMENSION DOES NOT INCLDE MOLD FLASH, PROTRSIONS OR GATE BRRS. MOLD FLASH, PROTRSIONS OR GATE BRRS SHALL NOT EXCEED.mm (.") PER SIDE. DIMENSION DOES NOT INCLDE INTERLEAD FLASH OR PROTRSIONS. INTERLEAD FLASH OR PROTRSIONS SHALL NOT EXCEED.mm (.") PER SIDE. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE.mm (.") MAX. ±. (. ±.) (NOTE ). (.) REF. ±. (. ±.) MSOP (MS) Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. fa

16 LT/LT TYPICAL APPLICATIO MHz Reference Distribution Amplifier MHz LABORATORY FREQENCY REFERENCE (dbm MAX) Ω.k nf k LT Ω nf V CC =.V Ω nf Ω nf Ω nf / TA RELATED PARTS PART NMBER DESCRIPTION COMMENTS LT/LT Dual/Triple MHz Current Feedback Amplifiers Shutdown, Operates to ±V LT/LT/LT Single, Dual, Quad MHz Current Feedback Amplifier V/µs Slew Rate LT/LT Dual/Triple MHz Current Feedback Amplifier.dB Gain Flatness to MHz, Shutdown LT/LT- MHz, Triple and Single RGB Multiplexer with MHz Pixel Switching, db Bandwidth: MHz, Current Feedback Amplifiers V/µs Slew Rate LT/LT Single/Dual, MHz, Rail-to-Rail Input and V/µs Slew Rate, Shutdown, Output Amplifiers Low Distortion dbc at MHz LT REV A PRINTED IN SA Linear Technology Corporation McCarthy Blvd., Milpitas, CA - () - FAX: () - LINEAR TECHNOLOGY CORPORATION fa

FEATURES APPLICATIONS TYPICAL APPLICATION LT1466L/LT1467L Micropower Dual/Quad Precision Rail-to-Rail Input and Output Op Amps

FEATURES APPLICATIONS TYPICAL APPLICATION LT1466L/LT1467L Micropower Dual/Quad Precision Rail-to-Rail Input and Output Op Amps Micropower Dual/Quad Precision Rail-to-Rail Input and Output Op Amps FEATRES Rail-to-Rail Input and Output Low Supply Current: 75µA Max 39µV V OS(MAX) for V CM = V to V + High Common Mode Rejection Ratio: