MAX388CWG ,High-Voltage, Fault-Protected Analog MultiplexersELECTRICAL CHARACTERISTICS (continued)
(V+ " 15v. v- = -15v. GND = WA = OV, AB = +2.4v, TA = +25'C ..
MAX388EPN ,High-Voltage, Fault-Protected Analog MultiplexersELECTRICAL CHARACTERISTICS (continued)
(V+ " 15v. v- = -15v. GND = WA = OV, AB = +2.4v, TA = +25'C ..
MAX388EWG ,High-Voltage, Fault-Protected Analog MultiplexersELECTRICAL CHARACTERISTICS
(V+ = 15V, V- = -15V, GND = WA = OV, Ag = +2.4V. TA = +25°C. unless oth ..
MAX3890ECB ,+3.3V / 2.5Gbps / SDH/SONET 16:1 Serializer with Clock Synthesis and LVDS InputsApplicationsOrdering Information2.5Gbps SDH/SONET Transmission SystemsPART TEMP. RANGE PIN-PACKAGE2 ..
MAX3892EGH+ ,+3.3V, 2.5Gbps/2.7Gbps, SDH/SONET 4:1 Serializer with Clock SynthesisApplications Ordering InformationSONET/SDH OC-48 Transmission SystemsTEMP PIN- PKG PART WDM Transpo ..
MAX3892EGH-TD ,+3.3V, 2.5Gbps/2.7Gbps, SDH/SONET 4:1 Serializer with Clock SynthesisELECTRICAL CHARACTERISTICS (continued)(V = +3.0V to +3.6V, T = -40°C to +85°C. Typical values are a ..
MAX742CPP ,Switch-Mode Regulator with +5V to 【12V or 【15V Dual Outputfeatures undervoltage lockout, thermal shut-down, and programmable soft-start. MAX742C/D 0°C to +70 ..
MAX742CWP ,Switch-Mode Regulator with +5V to 【12V or 【15V Dual OutputBlock DiagramDistributed Power Systems+5VComputer PeripheralsINPUTMAX742CC-__________________Pin Co ..
MAX742CWP ,Switch-Mode Regulator with +5V to 【12V or 【15V Dual OutputELECTRICAL CHARACTERISTICS(Circuit of Figure 2, V+ = 5V, 100/200 = 12/15 = 0V; T = T to T , unless ..
MAX742CWP ,Switch-Mode Regulator with +5V to 【12V or 【15V Dual OutputELECTRICAL CHARACTERISTICS(Circuit of Figure 2, +4.5V < V+ < +5.5V.)PARAMETER SYMBOL CONDITIONS MIN ..
MAX742CWP+ ,Switch-Mode Regulator with 5V to ±12 or ±15V Dual-OutputFeatures' Specs Guaranteed for In-Circuit PerformanceThe MAX742 DC-DC converter is a controller for ..
MAX742CWP-T ,Switch-Mode Regulator with 5V to ±12 or ±15V Dual-OutputBlock DiagramDistributed Power Systems+5VComputer PeripheralsINPUTMAX742CC-__________________Pin Co ..
MAX388CPN-MAX388CWG-MAX388EPN-MAX388EWG-MAX389EPN-MAX389EWG
High-Voltage, Fault-Protected Analog Multiplexers
19-0014.- Rav 2; 7M
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Gonoral Description
The MAX388 B-channel singIe-ended (I-ot-N and the
MAX389 4-channel differential (2-of-8) multiplexers
(muxes) with internal data latches use a high-voltage
series N-channel, P-channel, N-channel structure that
significantly improves fault protection over previous
devices. If power is removed with input voltages still
applied, all channels turn off, allowing only a few
nanoamperes of input leakage Current. This protects the
mux and output circuitry, as well as the signal sources
connected to the channel inputs.
When an overvoltage signal up to i1OOV(typically tl 10V)
is applied to an analog input or output, the channel turns
oft. To further protect output circuitry from on-channel
overvroltage, outputs are clamped to less than the power-
Foahn'co
. Fault and threevottrges Probation
. Fall-Safo with Pow Loss (No mehup)
. Brmtk-BetfttttFMaktt Switching
. All Channels Off when Power Ott
. Internal Data Latches
. TTL and CMOS Compatible
. Operates from M.5V to t18V Supplies
. On-Channels Turn Ott during Overvoltage
. Nanoampom Leakage In Overvoltage
Ordering Information
supply voltage. Since there is no increase in supply PART TEMP. RANGE PIN-PACKAGE
current during fault conditions, power dissipation does MAX388CPN 0°C to +70%: 18 Plastic DIP
not increase, The MAX388/MAX389 withstand full over- a a
voltage on any combination of channels, including all MAX388CJN 0 Cto +ro C 18 CERDIP
channels simultaneously. MAX388CWG 0°C to +70''C 24 so
All channel selection and control inputs are TTL and MAX388CID Otto t70''C Dice'
CMOS compatible. And, break-before-make switch MAX388EPN Mty'C to +85''C 18Plastic DIP
operation is guaranteed. MAX388EJN 40°C to t85''C 18 CERDIP
Appltca Hons MAX388EWG Mot to +85''C 24 so
Data-Acquisition Systems MAX388MJN -55°c to +125°c 18 CERDIP"
Industrial Process Control Systems
Avionics Test Equipment
Signal Routing Between Systems
Computer-Controlled Analog Data Logging
Ordcdng mum manned on tut p090.
'Cormct facrply " dice specifkatitms.
"Contact factory fixaeaitatglity and processing to MIL-STD! 8tt3.
Pln Configurations
TOP VIEW
Typical Operating Circuit m E . E is
.sv -sv A0 [E ii] MC
[-t==c=i-q m E E Al
" v- ' " E MAXIM Chl A2 (6N0)
MAXIM AeataAq v. E MAX368 iii] mu (W)
TL- (l', Mm INHIME W389 E Mme)
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- - mzs mtmE _ El M(me)
' - um
- - ms ”mu MINA) E Ciil mums)
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= " [E 14 "
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a'w L I , ouuoum E iril mam!!!)
_ TE rg AMI AMI 11TJ, Z ( )ARE FOR W389 so
''W/i'gi1'l& SYSTEM Pin Ctmtigwateons continued on last page.
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Fur free samples ' the latest literature: httptmeww.maxltttAearortt,
688WWIBEXVCU
MAX388/MAXMQ
High- Vollitage, Fatallbllihroitaitttardl
Analog Multiplexers
ABSOLUTE MAXIMUM RATINGS _
" to V- ........................................ 44V Continuous Power Dissipation
" to GND .w...twrr".w.--r.r---.. 22V 24-Pin SO (derate 11.7601ch above +70°C .............. 941mW
V- ttWND, .......................... _ ......... -22V 1B-Pin Plastic DIP (devate 11,1mW/‘C above 'rty'C) ..889mw
EN, WR RS. AGN .................... V+ + 4V to V- - 4V IB-Pin CERDIP (derate 10.53mWPC above +70°C) ..... 842mW
Analog Input with V4. = 15V, v. = -15V ............ tIOOV Operating Temperature Ranges
Analog Input mth V+ a V- = 0V .................. 11 15V MAX38_C_ -' ............... ..0"C to +70°C
Continuous Current, IN or OUT ................... 20mA MAX38_E_ _A. .. 40"C to +85°C
Peak Current. IN or OUT (Note 1) ................... 40mA MAX38_MJN ................... -55°C to +125°C
Not. 1: Pulsed at lms, 10% maximum duty cycle.
Storage Temperature Range
Lead Temperature (soldering. 10see)
AMPC to +150°C
.V_F..._..F.FF._l.. +300°C
Stresses be nd those listed under 'Absclure Maximwn Ranngs' may cause permanent damage to the demos mass are stress Iahngs only. and Imcrional
operalvon o the device at [hose or any other conditions: beyond those Indicated m the operational sechons of the specifications is not Implied. Exposure to
absolure manmum raring common: for extended penods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(V+ = 15V, V- = -15V. GND = W = 0V, Ag = +2.4V. TA = +25°C. unless otherwise noted.)
C. E SUFFIXES M SUFFIX
PARAMETER SYMBOL CONDITIONS MIN TYP MAX MIN TYP M AX UNITS
Analog Signal Range VANALOG (Note 4) -15 15 -15 15 V
Dram-Source r s ON VD = t10V. VAL = 0.8V 2 0 3.0 2.0 3.0 m
On Resistance D ( ) IS = 100PA, VAH = 2.4V TMAX 3.0 4.0 3.0 4.0
Greatest Change in
roswn) Between Aros(ON) -10V < VS < 10V 10 10 %
Channels
Source-Off Leakage I FF Van = 0.8V, VIN = t10V, 0.03 11.00 003 :050 nA
Current (Note 2) N0 ) VOUT a :10V TMAX 250 :50
0.1 22.0 0.1 21.0
Dram-Off VEN = 0.3v. W359 Tm t20° 2200
Leakage Current louT(oFF) VIN = t1tht, 2 0 l 0 nA
(Note 2) Vout = :10V MAX389 ' ' t .
TMAX 2:100 2100
:20 t20
Dram-On VEN = VAH = 2.41/, W388 TN :600 :1000
Leakage Current lounom Vou‘r = Vm = sttht, 20 20 nA
(Nole 2) VAL = 0.8V MAX389 A 1
TMAX 2300 1600
LOGIC INPUT
Logic Input Current [AH VA = 2.4V (Note 3) tl tl PA
(Input Voltage High) F VA = 14V (Note 3) tl tl
Logic input Current - - - I 1
(Input Voltage Low) IAL VEN = 0V or 2.4V, VA - Ag - WE - 0V t A HA
Output Leakage V :005 ' 10.02 M
. out = OV,
Current with louT(0FF) -
Overvonage VIN - 26W. (Note 5) TMAX 20 10 PA
Input Leakage W -
N - WN
Current with “N(OFF) - 40 25 UA
Overvoltage Vour - t10V, (Note 5)
Input Leakage - - =
Currentwim IIN(OFF) VIN: “(30M Pt - VOUT OV, 20 10 uA
. A0=A1=A2.-..0Vor5V
Power Supplies Ott