Pin Configurations/Functional Diagrams/Truth Tables IN V+ GND SOT23-6* MAX4544 ON OFF OFF ON SWITCHES SHOWN FOR "0" INPUT. Maxim Integrated Products 1

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1 9-; Rev ; / Low-Voltage, Single-Supply General Description The MAX MAX are precision, dual analog switches designed to operate from a single +.V to +V supply. Low power consumption (µw) makes these parts ideal for battery-powered equipment. These switches offer low leakage currents (pa max) and fast switching speeds (ton = ns max, toff = ns max). When powered from a +V supply, the MAX MAX offer Ω max matching between channels, Ω max on-resistance (R ON ), and Ω max RON flatness. These switches also offer pc max charge injection and a minimum of V ESD protection per Method.. The MAX/MAX/MAX are dual single-pole/ single-throw (SPST) devices and the MAX is a singlepole/double-throw (SPDT) device. The MAX has two normally open () switches and the MAX has two normally closed () switches. The MAX has one and one switch and can be used as an SPDT, while the MAX is an SPDT. The MAX/MAX/ MAX are available in tiny SOT- and QFN- packages, and the MAX is available in a SOT- package. Applications Battery-Operated Systems Sample-and-Hold Circuits Heads-Up Displays Guidance and Control Systems Audio and Video Switching Military Radios Test Equipment Communications Systems +V/+V DACs and ADCs PBX, PABX Cell Phones Ultrasound Pagers Features Low R ON : Ω max (Ω typ) RON Matching Between Channels: Ω max RON Flatness: Ω max Guaranteed Charge Injection: pc max +.V to +V Single-Supply Operation Low Power Consumption: <µw Low Leakage Current Over Temperature: na max at + C Fast Switching: t ON = ns, t OFF = ns Guaranteed Break-Before-Make (MAX/MAX only) TTL/CMOS-Logic Compatible Pin Compatible with MAX/MAX/MAX MAX// Available in SOT- MAX Available in SOT- PART Ordering Information TEMP RANGE P- PACKAGE Ordering Information continued at end of data sheet. *Dice are specified at T A = + C. TOP MARK MAXCUA C to + C µmax MAXCSA C to + C SO MAXCPA C to + C Plastic DIP MAXC/D C to + C Dice* MAXEKA-T - C to + C SOT- AAAE MAXEGA - C to + C QFN MAXEUA - C to + C µmax MAXESA - C to + C SO Pin Configurations/Functional Diagrams/Truth Tables MAX MAX TOP VIEW MAX MAX P MAX AAAM N.C. N.C. SOT-* µmax/so/dip/qfn MAX *TE: SOT- PACKAGE HAS LETTERG NEAREST P N.C. = T TERNALLY CONNECTED MAX/MAX/MAX APPEAR AT END OF DATA SHEET. ON OFF OFF ON SWITCHES SHOWN FOR "" PUT Maxim Integrated Products For pricing delivery, and ordering information please contact Maxim/Dallas Direct! at --9-, or visit Maxim s website at

2 MAX MAX ABSOLUTE MAXIMUM RATGS Voltage Referenced to...-.v to +V _, _, _, _ (Note )...-.V to ( +.V) Continuous Current (any terminal)...±ma Peak Current, _, _, _ (pulsed at ms, % duty cycle max)...±ma ESD per Method....>V Continuous Power Dissipation SOT- (derate.mw/ C above + C)...mW SOT- (derate.mw/ C above + C)...mW Note : QFN (derate.mw/ C above + C)...9mW µmax (derate.mw/ C above + C)...mW Narrow SO (derate.mw/ C above + C)...mW Plastic DIP (derate 9.9mW/ C above + C)...mW Operating Temperature Ranges MAX_C... C to + C MAX_E...- C to + C Storage Temperature Range...- C to + C Lead Temperature (soldering, s)...+ C Signals on,,, or exceeding or V- are clamped by internal diodes. Limit forward diode current to maximum current rating. 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 conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICSSingle +V Supply ( = +V ±%, =, V H =.V, V L =.V, T A = T M to T MAX, unless otherwise noted.) (Notes, ) PARAMETER ANALOG SWITCH Analog Signal Range On-Resistance On-Resistance Match Between Channels (Note ) On-Resistance Flatness (Note ) or Off-Leakage Current (Note ) Off-Leakage Current (Note ) On-Leakage Current (Note ) SYMBOL V, V, V R ON R ON R FLAT(ON) I (OFF) or I (OFF) I (OFF) I (ON) (Note ) =.V, I =.ma, V or V =.V = V, I =.ma, V or V =.V = V; I =.ma; V or V = V, V, V =.V; V = V,.V; V or V =.V, V =.V; V =.V, V; V or V = V,.V =.V; V = V,.V or V or V = V,.V, or floating CONDITIONS T A = + C T A = T M to T MAX T A = + C T A = T M to T MAX T A = + C T A = T M to T MAX T A = + C -... T A = T M to T MAX C, E - T A = + C -.. T A = T M to T MAX C, E - T A = + C -.. T A = T M to T MAX C, E M TYP MAX. - UNITS V Ω Ω Ω na na na

3 ELECTRICAL CHARACTERISTICSSingle +V Supply (continued) ( = +V ±%, =, V H =.V, V L =.V, T A = T M to T MAX, unless otherwise noted.) (Notes, ) DYNAMIC Turn-On Time Turn-Off Time PARAMETER Break-Before-Make Time Delay (Note ) Charge Injection (Note ) Off-Isolation (Note ) Crosstalk (Note 9) or Capacitance Off-Capacitance On-Capacitance SUPPLY Power-Supply Range Positive Supply Current PUT Input Voltage Low Input Voltage High SYMBOL t ON t OFF t D C L =.nf, V GEN =, R GEN =, T A = + C, Q Figure R L = Ω, C L = pf, f = MHz, T A = + C, OIRR Figure R L = Ω, C L = pf, f = MHz, T A = + C, Figure C OFF f = MHz, T A = + C, Figure C (OFF) f = MHz, T A = + C, Figure C (ON) I+ V L V H V or V = V, Figure V or V = V, Figure f = MHz, T A = + C, Figure CONDITIONS T A = + C T A = T M to T MAX T A = + C T A = T M to T MAX MAX/MAX only, R L = Ω, C L = pf MAX// MAX M TYP MAX. V =.V, V = or, all channels on or off -. µa UNITS ns ns ns pc db db pf pf pf V V MAX MAX

4 MAX MAX ELECTRICAL CHARACTERISTICSSingle +.V Supply ( = +.V to +.V, =, V H =.V, V L =.V, T A = T M to T MAX, unless otherwise noted.) (Notes, ) PARAMETER SYMBOL CONDITIONS M TYP MAX UNITS ANALOG SWITCH Analog Signal Range V, V, (Note ) V V Channel On-Resistance R ON I =.ma, = V, T A = + C V or V =.V T A = T M to T MAX DYNAMIC Turn-On Time (Note ) t ON V or V =.V Turn-Off Time (Note ) t OFF V or V =.V Break-Before-Make Time Delay (Note ) t D T A = + C T A = T M to T MAX T A = + C T A = T M to T MAX MAX/MAX only, R L = Ω, C L = pf, T A = + C ns ns ns Charge Injection (Note ) Q C L =.nf, V GEN =, R GEN =, T A = + C pc SUPPLY Positive Supply Current I+ =.V, V = or, all channels on or off - µa Ω Note : QFN and SOT-packaged parts are % tested at + C only and guaranteed by correlation at the full hot rated temperature. Note : The algebraic convention, where the most negative value is a minimum and the most positive value a maximum, is used in this data sheet. Note : Guaranteed by design. Note : R ON = R ON max - R ON min. Note : Flatness is defined as the difference between the maximum and minimum value of on-resistance as measured over the specified analog signal range. Note : Leakage parameters are % tested at maximum rated hot temperature and guaranteed by correlation at + C. Note : Off Isolation = log [V (V or V )], V = output, V or V = input to off switch. Note 9: Between the two switches, MAX/MAX/MAX only.

5 RON (Ω) Typical Operating Characteristics (T A = + C, unless otherwise noted.) ON-RESISTAE vs. VOLTAGE A: = +V B: = +V C: = +V A B V (V) C MAX- RON (Ω) ON-RESISTAE vs. VOLTAGE OVER TEMPERATURE A B C D E A: T A = + C B: T A = + C C: T A = + C D: T A = - C E: T A = - C V (V) MAX- ton/toff (ns) = +V t OFF TURN-ON/OFF TIMES vs. SUPPLY VOLTAGE t ON V SUPPLY (V) MAX- MAX MAX ton/toff (ns) 9 = +V TURN-ON/OFF TIMES vs. TEMPERATURE t ON t OFF MAX- ON/OFF-LEAKAGE (na).. ON/OFF-LEAKAGE CURRENT vs. TEMPERATURE = +.V I (ON) I /I N(OFF) MAX- Q (pc) CHARGE JECTION vs. VOLTAGE V- = +V MAX TEMPERATURE ( C) TEMPERATURE ( C) V (V) - - ON-LOSS FREQUEY RESPONSE MAX- 9 PUT VOLTAGE vs. SUPPLY CURRENT MAX- TOTAL HARMONIC DISTORTION vs. FREQUEY MAX-9 LOSS (db) ON-PHASE OFF-LOSS -9 Ω AND OUT = +V -. FREQUEY (MHz) PHASE (DEGREES) I+ (na) I V (V) THD (%). k k FREQUEY (Hz)

6 MAX MAX Pin Description Analog Switch Normally Open P DIP/SO/ µmax/ QFN MAX SOT- DIP/SO/ µmax/ QFN SOT- DIP/SO/ µmax/ SOT- DIP/SO/ µmax/ QFN QFN NAME MAX MAX, MAX SOT- N.C. FUTION Analog Switch Normally Open Analog Switch Common Digital Control Input GroundNegative Supply Input Analog Switch Normally Open Analog Switch Common Digital Control Input Positive Supply Voltage Input Analog Switch Normally Closed Analog Switch Normally Closed Analog SwitchNormally Open Analog SwitchCommon Analog SwitchNormally Closed Not Connected (open circuit) Digital Control Input V g POSITIVE SUPPLY D D Figure. Overvoltage Protection Using Two External Blocking Diodes Applications Information Logic Levels The MAX MAX are TTL compatible when powered from a single +V supply. When powered from other supply voltages, TTL compatibility is guaranteed and the logic inputs can be driven Rail-to-Rail. For example, with a +V supply, and can be driven low to and high to V. With a +.V supply, and should be driven low to and high to.v. Driving and rail-to-rail minimizes power consumption. Analog Signal Levels Analog signals that range over the entire supply voltage ( to ) can be switched with very little change in on-resistance over the entire voltage range (see Typical Operating Characteristics). All the switches are bidirectional, so the _, _, and _ pins can be used as either inputs or outputs. Rail-to-Rail is a registered trademark of Nippon Motorola, Ltd.

7 Power-Supply Sequencing and Overvoltage Protection Do not exceed the absolute maximum ratings because stresses beyond the listed ratings may cause permanent damage to the devices. Proper power-supply sequencing is recommended for all CMOS devices. Always apply before applying analog signals or logic inputs, especially if the analog or logic signals are not current limited. If this sequencing is not possible, and if the analog or logic inputs are not current limited to <ma, add a small-signal diode (D) as shown in Figure. If the analog signal can dip below, add D. Adding protection diodes reduces the analog signal range to a diode drop (about.v) below (for D), and to a diode drop above ground (for D). Leakage is unaffected by adding the diodes. On-resistance increases by a small amount at low supply voltages. Maximum supply voltage () must not exceed V. Adding protection diodes causes the logic thresholds to be shifted relative to the power-supply rails. This can be significant when low supply voltages (+V or less) are used. With a +V supply, TTL compatibility is not guaranteed when protection diodes are added. Driving and all the way to the supply rails (i.e., to a diode drop higher than the pin, or to a diode drop lower than the pin) is always acceptable. Protection diodes D and D also protect against some overvoltage situations. With Figure s circuit, if the supply voltage is below the absolute maximum rating, and if a fault voltage up to the absolute maximum rating is applied to an analog signal pin, no damage will result. MAX MAX Test Circuits/Timing Diagrams MAX MAX MAX MAX PUT SWITCH PUT or V R L k SWITCH OUTPUT V OUT C L pf PUT SWITCH OUTPUT +V % V OUT t ON t OFF tr < ns tf < ns.9 V UT.9 V OUT C L CLUDES FIXTURE AND STRAY CAPACITAE. V OUT = V ( R L R L + R ON ) PUT WAVEFORMS VERTED FOR SWITCHES THAT HAVE THE OPPOSITE SENSE. Figure. Switching Time

8 MAX MAX Test Circuits/Timing Diagrams (continued) MAX +V PUT R L Ω C L CLUDES FIXTURE AND STRAY CAPACITAE. Figure a. Break-Before-Make Interval (MAX only) V OUT C L pf R L Ω V OUT C L pf PUT SWITCH OUTPUT (V OUT ) SWITCH OUTPUT (V OUT ) +V % t D.9 V UT t D.9 V OUT MAX +V R L Ω V OUT C L pf PUT +V % PUT SWITCH OUTPUT (V OUT ).9 V OUT t D C L CLUDES FIXTURE AND STRAY CAPACITAE. Figure b. Break-Before-Make Interval (MAX only) MAX MAX MAX MAX V GEN R GEN OR _ C L V OUT V OUT OFF ON V OUT OFF V = +V OFF ON Q = ( V OUT )(C L ) OFF DEPENDS ON SWITCH CONFIGURATION; PUT POLARITY DETERMED BY SENSE OF SWITCH. Figure. Charge Injection

9 Test Circuits/Timing Diagrams (continued) SIGNAL GENERATOR dbm ANALYZER R L nf OR MAX MAX MAX MAX V OR.V SIGNAL GENERATOR dbm ANALYZER OR.V R L nf MAX MAX MAX Ω OR.V MAX MAX Figure. Off-Isolation Figure. Crosstalk nf MAX MAX MAX MAX TRANSISTOR COUNT: Chip Information CAPACITAE METER f = MHz OR OR.V Figure. Channel Off/On-Capacitance 9

10 MAX MAX Ordering Information (continued) PART TEMP RANGE *Dice are specified at T A = + C. P- PACKAGE TOP MARK MAXEPA - C to + C Plastic DIP MAXCUA C to + C µmax MAXCSA C to + C SO MAXCPA C to + C Plastic DIP MAXC/D C to + C Dice* MAXEKA-T - C to + C SOT- AAAF MAXEGA - C to + C QFN MAXEUA - C to + C µmax MAXESA - C to + C SO MAXEPA - C to + C Plastic DIP MAXCUA C to + C µmax MAXCSA C to + C SO MAXCPA C to + C Plastic DIP MAXC/D C to + C Dice* MAXEKA-T - C to + C SOT- AAAG MAXEGA - C to + C QFN MAXEUA - C to + C µmax MAXESA - C to + C SO MAXEPA - C to + C Plastic DIP MAXCUA C to + C µmax MAXCSA C to + C SO MAXCPA C to + C Plastic DIP MAXC/D C to + C Dice* MAXEUT-T - C to + C SOT- AAAM MAXEGA - C to + C QFN MAXEUA - C to + C µmax MAXESA - C to + C SO MAXEPA - C to + C Plastic DIP

11 Pin Configurations/Functional Diagrams/Truth Tables (continued) TOP VIEW MAX MAX MAX µmax/so/dip/qfn µmax/so/dip/qfn µmax/so/dip/qfn MAX MAX MAX MAX MAX SOT- SOT- SWITCHES SHOWN FOR "" PUT SOT-

12 MAX MAX Package Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to L, L QFN(DUAL).EPS µ

13 Package Information (continued) (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to SOT, L.EPS LSOT.EPS MAX MAX Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated Products, San Gabriel Drive, Sunnyvale, CA 9 -- Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.