+3V/+5V, 250MHz, SOT23 ADC Buffer Amplifiers with High-Speed Disable

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1 9-5; Rev ; / +V/+5V, 5MHz, SOT ADC Buffer Amplifiers General Description The MAX85/MAX86 single and MAX87/MAX88/ MAX87/MAX88 dual ADC buffer amplifiers feature high-speed performance and single +V supply operation. The MAX85/MAX86/MAX88 and MAX88 offer a disable feature that reduces power-supply current and places the outputs in a high-impedance state. All six devices operate from a +.85V to +6.5V single supply or from ±.5V to ±.5V dual supplies. The commonmode input voltage range extends to the negative powersupply rail (ground in single-supply applicatio). These devices require ma of quiescent supply current per amplifier while achieving a 5MHz -db bandwidth and a 5V/µs slew rate. The combination of an 8 (to.%) settling time, 88dBc (f = 5MHz) of SFDR, and up to ma output drive makes these amplifiers ideal for highspeed ADC drivers for communicatio and itrumentation applicatio. In addition, when disabled, their high output impedance makes them ideal for multiplexing applicatio. The MAX85/MAX86 are available in space-saving 6-pin SOT and 8-pin SO packages. The MAX87/ MAX87 come in 8-pin µmax and 8-pin SO packages, while the MAX88/MAX88 come in -pin µmax and -pin SO packages. High-Speed ADC Drivers Communicatio Equipment Itrumentation CCD Imaging Systems Ultrasound Applicatio Typical Operating Circuit appears at end of data sheet. Pin Configuratio appear at end of data sheet. Features High Speed at V 5MHz -db Bandwidth (MAX85/87/88) 5MHz -db Bandwidth (MAX86, MAX87/88) 5V/µs Slew Rate +.85V to +6.5V Single-Supply Operation Input Common-Mode Range Extends to V EE Low Distortion at 5MHz -88dBc SFDR High Output Current Drive: -6mA to +77mA 6 Settling Time to.% High-Speed Enable/Disable Enable Time 5 Disable Time High Output Impedance Space-Saving SOT and µmax Packages PART Ordering Information TEMP. RANGE PIN- PACKAGE MAX85EUT-T - C to +85 C 6 SOT-6 AABQ Ordering Information continued at end of data sheet. SOT TOP MARK MAX85ESA - C to +85 C 8 SO MAX86EUT-T - C to +85 C 6 SOT-6 AABR MAX86ESA - C to +85 C 8 SO MAX87EUA - C to +85 C 8 µmax MAX87ESA - C to +85 C 8 SO Selector Guide PART OP AMPS PER PKG MIN GAIN -db BANDWIDTH (AT MIN GAIN) HIGH-SPEED DISABLE PIN-PACKAGE MAX85 5MHz Yes 6-pin SOT, 8-pin SO MAX86 5 5MHz Yes 6-pin SOT, 8-pin SO MAX87 5MHz No 8-pin µmax/so MAX88 5MHz Yes -pin µmax/-pin SO MAX87 5 5MHz No 8-pin µmax/so MAX88 5 5MHz Yes -pin µmax, -pin SO Maxim Integrated Products For free samples and the latest literature, visit or phone For small orders, phone

2 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers ABSOLUTE MAXIMUM RATINGS Supply Voltage (V CC - V EE )...-.V to +7.5V Input Voltage Range (IN+, IN-)...(V EE -.V) to (V CC +.V) Differential Input Voltage...-.V to +7.5V Voltage at DISABLE...(V EE -.V) to (V CC +.V) Current into IN+, IN-, DISABLE...±mA Output Short-Circuit Duration...Indefinite Continuous Power Dissipation (T A = +7 C) 6-Pin SOT (derate 7.mW/ C above +7 C)...57mW Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditio beyond those indicated in the operational sectio of the specificatio is not implied. Exposure to absolute maximum rating conditio for extended periods may affect device reliability. DC ELECTRICAL CHARACTERISTICS 8-Pin µmax (derate.mw/ C above +7 C)...mW -Pin µmax (derate 5.6mW/ C above +7 C)...mW 8-Pin SO (derate 5.88mW/ C above +7 C)...7mW -Pin SO (derate 8.mW/ C above +7 C)...667mW Operating Temperature Range...- C to +85 C Junction Temperature...+5 C Storage Temperature Range C to +5 C Lead Temperature (soldering, s)...+ C (V CC = +V, V EE =, DISABLE_ = V, R L =, V CM = V, and T A = T MIN to T MAX, unless otherwise noted. Typical values are at T A = +5 C.) (Note ) PARAMETER Operating Supply Voltage Range Input Common-Mode Voltage Range Input Offset Voltage Input Offset-Voltage Temperature Coefficient Input Offset-Voltage Matching Input Bias Current Input Offset Current Input Resistance Common-Mode Rejection Ratio SYMBOL V CM V OS TC VOS V OS I B I OS Guaranteed by PSRR test Guaranteed by CMRR test MAX_87EU_/MAX_88EU_/MAX_8_ES_ MAX87/88 and MAX87/88 Differential (-mv V IN +mv) 8 R IN Common mode (V EE V CM V CC -.5V) 6 CMRR V EE V CM V CC -.5V CONDITIONS MIN TYP MAX V EE V CC -.5 ±. ±8 MAX85EUT-T/MAX86EUT-T ±.5 ± MAX_87EU_/ MAX_88EU_/ MAX_8_ES_ MAX85EUT-T/ MAX86EUT-T 6 ± UNITS V V mv µv/ C mv µa µa kω db R L = kω 75 9 Open-Loop Gain A VOL VEE +.V V OUT V CC -.V R L = Ω 65 9 R L = Ω 6 85 db

3 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers DC ELECTRICAL CHARACTERISTICS (continued) (V CC = +V, V EE =, DISABLE_ = V, R L =, V CM = V, and T A = T MIN to T MAX, unless otherwise noted. Typical values are at T A = +5 C.) (Note ) PARAMETER Output Current Drive Power-Supply Rejection Ratio Disabled Output Leakage Current DISABLE_ Logic Low Threshold DISABLE_ Logic Input Low Current DISABLE_ Logic Input High Current Quiescent Supply Current (per Amplifier) SYMBOL I OUT PSRR I LEAK V IL I IL I IH I SY CONDITIONS MIN TYP MAX R L = Ω to V EE 77 R L = Ω to V CC 6 V CC =.85V to 6.5V DISABLE_ = V EE, V EE V OUT V CC DISABLE_ = V EE ± ± µa DISABLE_ = V CC V CC = V V CC = 5V Normal mode ± ± Disabled mode, DISABLE_ = V EE Normal mode 5 7 V CC - DISABLE_ Logic High Threshold V IH V CC - V 8 Disabled mode, DISABLE_ = V EE UNITS ma db na V µa ma

4 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers AC ELECTRICAL CHARACTERISTICS (V CC = +V, V EE =, DISABLE_ = V, R L = Ω to V CC /, V CM = V, A VCL = +V/V for MAX85/MAX87/MAX88, A VCL = +5V/V for MAX86 and MAX87/MAX88, T A = +5 C, unless otherwise noted.) Small-Signal -db Bandwidth Bandwidth for.db Flatness Slew Rate Rise Time Fall Time PARAMETER Large-Signal -db Bandwidth Settling Time (.%) Overload Recovery Time Spurious-Free Dynamic Range Two-Tone Third-Order Intercept Input Noise Voltage Deity Input Noise Current Deity Input Capacitance Output Impedance Enable Time Disable Time Crosstalk SYMBOL BW SS BW LS BW.dB SR t R t F t S.% SFDR IP e n i n C IN Z OUT t ON t OFF X TALK CONDITIONS MAX85/87/88 V OUT = mvp-p MAX86 and MAX87/88 V OUT = Vp-p V OUT = mvp-p MAX85/87/88 MAX86 and MAX87/88 V OUT = V step, % to 9% V OUT = V step, % to 9% V OUT = V step, 9% to % MAX85/87/88 V OUT = V step MAX86 and MAX87/88 % overdrive V OUT =.5Vp-p f C = MHz f = MHz f = MHz f = MHz V OUT = V, to within.% V OUT = V, to within.% f C = khz f C = MHz f C = 5MHz f C = MHz f C = MHz f C = 6MHz MAX87/88 and MAX87/88, f = MHz, V OUT = Vp-p MIN TYP MAX UNITS MHz MHz MHz V/µs dbc dbm nv/ Hz pa/ Hz pf Ω dbc

5 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers AC ELECTRICAL CHARACTERISTICS (continued) (VCC = +5V, V EE =, DISABLE_ = 5V, R L = Ω to V CC /, V CM =.5V, A VCL = +V/V for MAX85/MAX87/MAX88, A VCL = +5V/V for MAX86 and MAX87/MAX88, T A = +5 C, unless otherwise noted.) Small-Signal -db Bandwidth Large-Signal -db Bandwidth Slew Rate Rise Time Fall Time PARAMETER Bandwidth for.db Flatness Settling Time (.%) Spurious-Free Dynamic Range Two-Tone Third-Order Intercept Input Noise Voltage Deity Input Noise Current Deity Input Capacitance Output Impedance Enable Time Disable Time Crosstalk SYMBOL BW SS BW LS BW.dB SR t R t F t S.% SFDR IP e n i n C IN Z OUT t ON t OFF X TALK V OUT = mvp-p V OUT = Vp-p V OUT = mvp-p V OUT = Vp-p f C = MHz f = MHz CONDITIONS MAX85/87/88 MAX86 and MAX87/88 MAX85/87/88 MAX86 and MAX87/88 V OUT = V step, % to 9% V OUT = V step, % to 9% V OUT = V step, 9% to % MAX85/87/88 V OUT = V step MAX86 and MAX87/88 f C = khz f C = MHz f = MHz f = MHz V OUT = V, to within.% V OUT = V, to within.% f C = 5MHz f C = MHz f C = MHz f C = 6MHz MAX87/88 and MAX87/88, f = MHz, V OUT = Vp-p MIN TYP MAX UNITS MHz MHz MHz V/µs dbc dbm nv/ Hz pa/ Hz pf Ω dbc Note : The MAX8_EUT (SOT) are % production tested at T A = +5 C. Specificatio over temperature limits are guaranteed by design. 5

6 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers MAX85/MAX87/MAX88 SMALL-SIGNAL GAIN vs. FREQUENCY -6 k M M M k M M A V = +V/V MAX85/MAX87/MAX88 GAIN FLATNESS vs. FREQUENCY (R LOAD = Ω) A V = +V/V M LARGE-SIGNAL GAIN vs. FREQUENCY -6 k M M M MA85- MA85- MA MAX86/MAX87/MAX88 SMALL-SIGNAL GAIN vs. FREQUENCY -6 k M M M k M M MAX85/MAX87/MAX88 GAIN FLATNESS vs. FREQUENCY (R LOAD = kω) A V = +V/V M MAX85/MAX87/MAX88 DISTORTION vs. FREQUENCY R L = Ω V OUT =.5Vp-p A V = +V/V ND HARMONIC RD HARMONIC -. FREQUENCY (MHz) Typical Operating Characteristics (V CC = +V, V EE =, DISABLE_ V, R L = Ω to VCC/, V CM = +.V, T A =+5 C, unless otherwise noted.) MA85- MA85-5 MAX MAX85/MAX87/MAX88 GAIN FLATNESS vs. FREQUENCY (R LOAD = Ω) -.5 k M M A V = +V/V M MAX86/MAX87/MAX88 GAIN FLATNESS vs. FREQUENCY R LOAD = Ω R LOAD = kω -.6 k M M M R LOAD = Ω MAX86/MAX87/MAX88 DISTORTION vs. FREQUENCY R L = Ω V OUT =.5Vp-p ND HARMONIC RD HARMONIC -. FREQUENCY (MHz) MA85- MA85-6 MAX85-9 6

7 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Typical Operating Characteristics (continued) (V CC = +V, V EE =, DISABLE_ V, R L = Ω to VCC/, V CM = +.V, T A =+5 C, unless otherwise noted.) DISTORTION (dbc) DISTORTION (dbc) MAX85/MAX87/MAX88 DISTORTION vs. LOAD f O = MHz V OUT =.5Vp-p A V = +V/V ND HARMONIC RD HARMONIC RESISTIVE LOAD (Ω) MAX86/MAX87/MAX88 DISTORTION vs. SWING R L = Ω f O = MHz ND HARMONIC RD HARMONIC VOLTAGE (Vp-p) MAX85- MAX85- DISTORTION (dbc) OFF-ISOLATION MAX85/MAX87/MAX88 LARGE-SIGNAL PULSE RESPONSE (A V = +V/V) MAX86/MAX87/MAX88 DISTORTION vs. LOAD f O = MHz V OUT =.5Vp-p RD HARMONIC ND HARMONIC RESISTIVE LOAD (Ω) MAX85/MAX86/MAX88/MAX88 OFF-ISOLATION vs. FREQUENCY - k M M M MAX85- MA85-5 DISTORTION (dbc) MAX85/MAX87/MAX88 DISTORTION vs. SWING R L = Ω f O = MHz A V = +V/V ND HARMONIC RD HARMONIC VOLTAGE (Vp-p) MAX87/MAX88/MAX87/MAX88 CROSSTALK vs. FREQUENCY. FREQUENCY (MHz) MAX86/MAX87/MAX88 LARGE-SIGNAL PULSE RESPONSE () MAX85- MAX85-6 INPUT 5mV/ MA85-7 INPUT mv/ VOLTAGE (V) VOLTAGE (V) MA85-8 OUTPUT 5mV/ OUTPUT 5mV/ TIME (5/) TIME (5/) 7

8 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Typical Operating Characteristics (continued) (V CC = +V, V EE =, DISABLE_ V, R L = Ω to VCC/, V CM = +.V, T A =+5 C, unless otherwise noted.) INPUT 5mV/ VOLTAGE (V) OUTPUT 5mV/ INPUT mv/ VOLTAGE (V) OUTPUT 5mV/ PSRR (db) MAX85/MAX87/MAX88 SMALL-SIGNAL PULSE RESPONSE (A V = +V/V) TIME (5/) MAX86/MAX87/MAX88 SMALL-SIGNAL PULSE RESPONSE (C LOAD = 7pF, ) TIME (5/) POWER-SUPPLY REJECTION RATIO vs. FREQUENCY -6 k M M M MA85-9 MA85- MA85-7 INPUT mv/ VOLTAGE (V) OUTPUT 5mV/ RISO (Ω) CMR (db) MAX86/MAX87/MAX88 SMALL-SIGNAL PULSE RESPONSE () TIME (5/) ISOLATION RESISTANCE vs. LOAD CAPACITANCE MAX86/MAX87/MAX88 MAX85/87/88 A V = +V/V C LOAD (pf) COMMON-MODE REJECTION vs. FREQUENCY - k M M M MA85- MAX85- MA85-8 IMPEDANCE (Ω) INPUT 5mV/ VOLTAGE (V) OUTPUT 5mV/ TIME () MAX85/MAX87/MAX88 SMALL-SIGNAL PULSE RESPONSE (C LOAD = pf, A V = +V/V) TIME (5/) GROUP DELAY vs. FREQUENCY k M M M OUTPUT IMPEDANCE vs. FREQUENCY k k M M M MA85- MA85-6 MAX85-9 8

9 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Typical Operating Characteristics (continued) (V CC = +V, V EE =, DISABLE_ V, R L = Ω to VCC/, V CM = +.V, T A =+5 C, unless otherwise noted.) VOLTAGE NOISE (nv/ Hz) INPUT OFFSET CURRENT (µa) VOLTAGE NOISE DENSITY vs. FREQUENCY k k k M M INPUT OFFSET CURRENT vs. TEMPERATURE TEMPERATURE ( C) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY (C LOAD = pf) - k M M M MAX85- MAX85- MA85-9 NOISE (pa/ Hz) INPUT OFFSET VOLTAGE (mv) CURRENT NOISE DENSITY vs. FREQUENCY k k k M M INPUT OFFSET VOLTAGE vs. TEMPERATURE TEMPERATURE ( C) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY (C LOAD = 7pF) - k M M M MAX85- MAX85- MA85- INPUT BIAS CURRENT (µa) POWER-SUPPLY CURRENT (ma) INPUT BIAS CURRENT vs. TEMPERATURE TEMPERATURE ( C) POWER-SUPPLY CURRENT vs. TEMPERATURE TEMPERATURE ( C) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY (C LOAD = 7pF) - k M M M MAX85- MAX85-5 MA85-9

10 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Typical Operating Characteristics (continued) (V CC = +V, V EE =, DISABLE_ V, R L = Ω to VCC/, V CM = +.V, T A =+5 C, unless otherwise noted.) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY C LOAD R ISO (C LOAD = 7pF) -.5 k M M M V CC - V V EE + V R ISO = 5Ω MA ENABLE/DISABLE RESPONSE TIME (V CC = 5V) TIME (/) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY C LOAD R ISO (C LOAD = 7pF) -.5 k M M M MA85-5 V CC - V V EE + V R ISO = Ω MA ENABLE/DISABLE RESPONSE TIME (V CC = V) TIME (/) MAX86 SMALL-SIGNAL GAIN vs. FREQUENCY C LOAD R ISO (C LOAD = 7pF) R ISO = 5Ω -.5 k M M M MA85-6 MA85-

11 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers 6-PIN SOT-6 MAX85 MAX86 8-PIN SO PIN MAX87 MAX87 8-PIN µmax/so -PIN µmax MAX88 MAX88 -PIN SO, 5 5, 7, 8, N.C. 6 OUT V EE IN+ IN- 5 8 DISABLE 5 6 DISABLEA 6 9 DISABLEB V CC OUTA INA- INA+ 5 7 INB+ 6 8 INB- 7 9 OUTB Detailed Description The MAX85 MAX88 and MAX87/MAX88 are voltage-feedback op amps, intended for use as ADC input buffers. They operate from a single +.85V to +6.5V supply or dual ±.5V to ±.5V supplies. Their high output drive, wide bandwidth, fast settling, low noise, and low distortion make them ideal for the brutal task of meeting the dynamic input drive requirements of high-speed ADCs or other demanding applicatio. The MAX85/MAX86/MAX88 and MAX88 have a high-speed disable mode that places the outputs in a high-impedance state and lowers operating supply current to ma. The enable time is typically, and the disable time is typically 5. The MAX85/MAX86 have a single enable pin (DISABLE), and the MAX88/ NAME Pin Description Amplifier B Noninverting Input Amplifier B Inverting Input Amplifier B Output FUNCTION Not Internally Connected. Connect to ground or leave unconnected. Amplifier Output Negative Power Supply, or Ground in Single-Supply Operation Noninverting Input Inverting Input Disable (active low) Disable Amplifier A (active low) Disable Amplifier B (active low) Positive Power Supply Amplifier A Output Amplifier A Inverting Input Amplifier A Noninverting Input MAX88 have dual disable pi (DISABLEA, DISA- BLEB). The MAX85/MAX87/MAX88 are internally compeated for unity-gain stability. The MAX86/ MAX87/MAX88 are compeated for gai of +5V/V or greater. Applicatio Information Inverting and Noninverting Configuratio Select the gain-setting feedback (R F ) and input (R G ) resistor values coidering the following criteria: large resistor values increase voltage noise and interact with the amplifier s input and PC board capacitance to effect system bandwidth. This generates undesirable poles and zeros that decrease bandwidth or cause oscillatio.

12 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers For example, a noninverting gain-of-two configuration (R F = R G ) using kω resistors, combined with pf typical amplifier input capacitance, generates a pole at 59MHz. Since this pole is within the amplifier bandwidth, it jeopardizes stability. Reducing these kω resistors to Ω extends the pole frequency to.59ghz, but affects output swing by adding Ω in parallel with the amplifier s load resistor. The typical value for R F is Ω. Layout and Power-Supply Bypassing These amplifiers operate from a single +.85V to +6.5V power supply or from ±.5V to ±.5V dual supplies. For single-supply operation, bypass V CC to ground with a.nf capacitor as close to the pin as possible, with a.µf capacitor in parallel. If operating with dual supplies, bypass each supply with capacitors to ground. Observe the following guidelines: A solid ground plane is essential for good high-frequency behavior. Where possible, use multiple ground vias. Use a PC board with at least two layers. Avoid areas of unreferenced copper-clad. Keep signal traces as short and as straight as possible. Do not make sharp tur; round all trace corners. Use a cotant-impedance board design if possible. High-Speed Disable The MAX85/MAX86/MAX88 and MAX88 feature a disable (DISABLE_) input that places the amplifier in a low-power, high-output-impedance state. When DISABLE_ is asserted, the amplifier s output impedance is typically 5kΩ. This high output impedance, combined with the low pf output capacitance, make these devices ideal for ADC input multiplexing applicatio or switch applicatio. Typical enable/disable times are /5. Output Capacitive Loading and Stability These op amps are optimized for AC performance. They are not designed to drive highly reactive loads, which decrease phase margin and may produce excessive ringing and oscillation. A small isolation resistor (usually Ω to Ω) placed before the reactive load reduces possible ringing and oscillation (Figure ). At higher capacitive loads, AC performance is dependent on the interaction of the load capacitance, the isolation resistor, and on-board layout. Output Drive Capability The MAX85 MAX88 and MAX87/MAX88 have an output sink capability of 6mA and a source capability of 77mA. This high current ability allows them to drive low-impedance and dynamic-impedance ADC inputs. The linear output range of these devices is (V EE +.V) to (V CC -.V). Operation beyond this range is not recommended due to reduced gain and phase margin. R G R F MAX85 MAX86 MAX87 MAX88 MAX87 MAX88 Figure. Using an Isolation Resistor (R S ) for High Capacitive Loads R S C I C I

13 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Ordering Information (continued) PART MAX88EUB MAX88ESD MAX87EUA MAX87ESA MAX88EUB MAX88ESD TEMP. RANGE - C to +85 C - C to +85 C - C to +85 C - C to +85 C - C to +85 C - C to +85 C PIN- PACKAGE µmax SO 8 µmax 8 SO µmax SO SOT TOP MARK Chip Information TRANSISTOR COUNT: MAX85/MAX86 : MA87/MAX88/ MAX87/MAX88 : 7 TOP VIEW OUT V EE VEE MAX85 MAX86 6 V CC IN+ IN+ 6-PIN SOT 5 DISABLE MAX88 MAX88 N.C. IN+ V EE MAX85 MAX86 8-PIN SO R G OUT N.C. V IN DISABLE V CC Typical Operating Circuit R F OUTA MAX88 MAX88 INB- INA- INA+ V EE MAX85 MAX86 MAX87 MAX88 MAX87 MAX88 MAX87 MAX87 8-PIN SO/µMAX MAX57 A/D CONVERTER Pin Configuratio V CC OUTB IN- IN- INB+ OUTA V CC OUTA V CC INA- 9 OUTB INA- OUTB INA+ 8 INB- INA+ INB- V EE 7 INB+ V EE INB+ DISABLEA 5 6 DISABLEB N.C. 5 N.C. -PIN µmax DISABLEA N.C DISABLEB N.C. -PIN SO

14 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Package Information 8LUMAXD.EPS 6LSOT.EPS

15 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Package Information (continued) LUMAX.EPS 5

16 +V/+5V, 5MHz, SOT ADC Buffer Amplifiers Package Information (continued) SOICN.EPS Maxim cannot assume respoibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licees are implied. Maxim reserves the right to change the circuitry and specificatio without notice at any time. 6 Maxim Integrated Products, San Gabriel Drive, Sunnyvale, CA Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.

Single-Supply, 150MHz, 16-Bit Accurate, Ultra-Low Distortion Op Amps

Single-Supply, 150MHz, 16-Bit Accurate, Ultra-Low Distortion Op Amps 9-; Rev ; /8 Single-Supply, 5MHz, 6-Bit Accurate, General Description The MAX4434/MAX4435 single and MAX4436/MAX4437 dual operational amplifiers feature wide bandwidth, 6- bit settling time in 3ns, and