Dual/Triple, Ultra-Low-Voltage, SOT23 μp Supervisory Circuits MAX6715A MAX6729A/ MAX6797A

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1 General Description The are ultra-lowvoltage microprocessor (μp) supervisory circuits designed to monitor two or three system power-supply voltages. These devices assert a system reset if any monitored supply falls below its factory-trimmed or adjustable threshold and maintain reset for a minimum timeout period after all supplies rise above their thresholds. The integrated dual/triple supervisory circuits significantly improve system reliability and reduce size compared to separate ICs or discrete components. These devices monitor primary supply voltages ( ) from 1.8V to 5.0V and secondary supply voltages (V CC ) from 0.9V to 3.3V with factory-trimmed reset threshold voltage options (see the Reset Voltage Threshold Suffix Guide). An externally adjustable IN input option allows customers to monitor a third supply voltage down to 0.6V. These devices are guaranteed to be in the correct reset output logic state when either or V CC remains greater than 0.8V. A variety of push-pull or open-drain reset outputs along with watchdog input, manual-reset input, and power-fail input/output features are available (see the Selector Guide). Select reset timeout periods from 1.1ms to 110ms (min) (see the Reset Timeout Period Suffix Guide). The are available in small 5-, 6-, and 8-pin SOT3 packages and operate over the -40 C to +15 C temperature range. Applications Multivoltage Systems Industrial Equipment Telecom/Networking Printers/Fax Machines Equipment Set-Top Boxes Computers/Servers Portable/Battery- Operated Equipment Features (Primary Supply) Reset Threshold Voltages from 1.58V to 4.63V V CC (Secondary Supply) Reset Threshold Voltages from 0.79V to 3.08V Externally Adjustable IN Threshold for Auxiliary/ Triple-Voltage Monitoring (0.6V Internal Reference) Watchdog Timer Option 35s (min) Long Startup Period 1.1s (min) Normal Timeout Period Manual-Reset Input Option Power-Fail Input/Power-Fail Output Option (Push-Pull and Open-Drain Active-Low) Guaranteed Reset Valid Down to or V CC = 0.8V Reset Output Logic Options Immune to Short V CC Transients Low Supply Current 14μA (typ) at 3.6V Watchdog Disable Feature Small 5, 6, and 8-Pin SOT3 Packages AEC-Q100 Qualified: MAX6719AUTTWD1/V+T Ordering Information continued at end of data sheet. Pin Description and Selector Guide appear at end of data sheet. Typical Operating Circuit UNREGULATED DC R1 R IN DC-DC OUT CONVERTER OUT1 PUSHBUTTON SWITCH V CC MAX6715A- MAX679A/ IN/PFI WDI PFO MAX67 1.8V 0.9V I/O CORE SUPPLY SUPPLY RESET I/O µp NMI ; Rev 5; 10/17

2 Absolute Maximum Ratings Terminal Voltage (with respect to ), V CC V to +6V Open-Drain, 1,, PFO, V to +6V Push-Pull, 1, PFO, V to ( + 0.3V) Push-Pull V to (V CC + 0.3V) IN, PFI,, WDI V to +6V Input Current/Output Current (all pins)...0ma Continuous Power Dissipation (T A = +70 C) 5-Pin SOT3-5 (derate 7.1mW/ C above +70 C)...571mW 6-Pin SOT3-6 (derate 8.7mW/ C above +70 C)...696mW 8-Pin SOT3-8 (derate 8.9mW/ C above +70 C)...714mW Operating Temperature Range C to +15 C Storage Temperature Range C to +150 C Junction Temperature C Lead Temperature (soldering, 10s) C 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 Characteristics ( = 0.8V to 5.5V, V CC = 0.8V to 5.5V, = 0V, T A = -40 C to +15 C, unless otherwise noted. Typical values are at T A = +5 C.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS Supply Voltage V CC V Supply Current I CC1 I CC < 5.5V all I/O connections open, outputs not asserted < 3.6V all I/O connections open, outputs not asserted V CC < 3.6V all I/O connections open, outputs not asserted V CC <.75V all I/O connections open, outputs not asserted µa L (falling) M (falling) T (falling) S (falling) Reset Threshold V TH1 R (falling) V Z (falling) Y (falling) W (falling) V (falling) T (falling) S (falling) R (falling) Z (falling) Y (falling) W (falling) V CC Reset Threshold V TH V (falling) V I (falling) H (falling) G (falling) F (falling) E (falling) D (falling) Maxim Integrated

3 Electrical Characteristics (continued) ( = 0.8V to 5.5V, V CC = 0.8V to 5.5V, = 0V, T A = -40 C to +15 C, unless otherwise noted. Typical values are at T A = +5 C.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS Reset Threshold Tempco ΔV TH / C 0 ppm/ C Reset Threshold Hysteresis V HYST Referenced to V TH typical 0.5 % V CC to Reset Output Delay t RD = (V TH mV) to (V TH1-100mV) or V CC = (V TH + 75mV) to (V TH - 75mV) Reset Timeout Period t RP 0 µs D D D7 ( only) D8 ( only) D D D D ADJUSTABLE RESET COMPARATOR INPUT (MAX6719A/MAX670A/MAX673A MAX677A) IN Input Threshold V IN mv IN Input Current I IN na IN Hysteresis 3 mv IN to Reset Output Delay t IND V IN to (V IN - 30mV) µs POWER-FAIL INPUT (MAX678A/MAX679A) PFI Input Threshold V PFI mv PFI Input Current I PFI na PFI Hysteresis V PFH 3 mv PFI to PFO Delay t DPF (V PFI + 30mV) to (V PFI - 30mV) µs MANUAL-RESET INPUT (MAX6715A MAX67A/MAX675A MAX679A) V IL 0.3 x Input Voltage V IH 0.7 x V Minimum Pulse Width 1 µs Glitch Rejection 100 ns to Reset Delay t 00 ns Pullup Resistance kω WATCHDOG INPUT (MAX671A MAX679A) First watchdog period after reset timeout Watchdog Timeout Period t WD period s Normal mode WDI Pulse Width t WDI (Note ) 50 ns V IL 0.3 x WDI Input Voltage V V IH 0.7 x WDI Input Current I WDI V WDI = 0V or µa ms Maxim Integrated 3

4 Electrical Characteristics (continued) ( = 0.8V to 5.5V, V CC = 0.8V to 5.5V, = 0V, T A = -40 C to +15 C, unless otherwise noted. Typical values are at T A = +5 C.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS RESET/POWER-FAIL OUTPUTS or V CC 0.8V, I SINK = 1µA, output asserted 0.3 /1//PFO Output Low (Push-Pull or Open-Drain) /1/PFO Output High (Push-Pull Only) Output High (Push-Pull Only) Output High (Push-Pull Only) Output Low (Push-Pull or Open Drain) /1//PFO Output Open-Drain Leakage Current Output Open-Drain Leakage Current V OL V OH V OH V OH V OL or V CC 1.0V, I SINK = 50µA, output asserted or V CC 1.V, I SINK = 100µA, output asserted or V CC.7V, I SINK = 1.mA, output asserted or V CC 4.5V, I SINK = 3.mA, output asserted 1.8V, I SOURCE = 00µA, output not asserted.7v, I SOURCE = 500µA, output not asserted 4.5V, I SOURCE = 800µA, output not asserted 1.8V, I SOURCE = 00µA, output not asserted.7v, I SOURCE = 500µA, output not asserted 4.5V, I SOURCE = 800µA, output not asserted 1.0V, I SOURCE = 1µA, reset asserted 1.8V, I SOURCE = 150µA, reset asserted.7v, I SOURCE = 500µA, reset asserted 4.5V, I SOURCE = 800µA, reset asserted or V CC 1.8V, I SINK = 500µA, reset not asserted or V CC.7V, I SINK = 1.mA, reset not asserted or V CC 4.5V, I SINK = 3.mA, reset not asserted 0.8 x 0.8 x 0.8 x 0.8 x V CC 0.8 x V CC 0.8 x V CC 0.8 x 0.8 x 0.8 x 0.8 x Output not asserted 0.5 µa Output asserted 0.5 µa V V V V V Note 1: Devices tested at T A = +5 C. Overtemperature limits are guaranteed by design and not production tested. Note : Parameter guaranteed by design. Maxim Integrated 4

5 Typical Operating Characteristics ( = 5V, V CC = 3.3V, T A = +5 C, unless otherwise noted.) SUPPLY CURRENT (µa) SUPPLY CURRENT (µa) RESET THRESHOLD SUPPLY CURRENT vs. TEMPERATURE (V CC 1 = +5V, V CC = +3.3V) TOTAL I CC 1 I CC SUPPLY CURRENT vs. TEMPERATURE (V CC 1 = +1.8V, V CC = +1.V) TOTAL I CC 1 I CC NORMALIZED V CC RESET THRESHOLD vs. TEMPERATURE MAX6715A-9A toc01 MAX6715A-9A toc04 MAX6715A-9A toc07 SUPPLY CURRENT (µa) RESET/WATCHDOG TIMEOUT PERIOD RESET THRESHOLD SUPPLY CURRENT vs. TEMPERATURE (V CC 1 = +3.3V, V CC = +.5V) TOTAL I CC 1 I CC NORMALIZED/RESET WATCHDOG TIMEOUT PERIOD vs. TEMPERATURE RESET INPUT AND POWER-FAIL INPUT THRESHOLD vs. TEMPERATURE MAX6715A-9A toc0 MAX6715A-9A toc05 MAX6715A-9A toc08 SUPPLY CURRENT (µa) MAXIMUM VCC TRANSIENT DURATION (µs) VCC TO RESET DELAY (µs) , SUPPLY CURRENT vs. TEMPERATURE (V CC 1 = +.5V, V CC = +1.8V) TOTAL I CC 1 I CC MAXIMUM V CC TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVE RESET OCCURS ABOVE THIS LINE RESET THRESHOLD OVERDRIVE (mv) V CC TO RESET DELAY vs. TEMPERATURE mV OVERDRIVE MAX6715A-9A toc03 MAX6715A-9A toc06 MAX6715A-9A toc09 Maxim Integrated 5

6 Typical Operating Characteristics (continued) ( = 5V, V CC = 3.3V, T A = +5 C, unless otherwise noted.) IN TO RESET DELAY (µs) IN INPUT TO RESET OUTPUT DELAY vs. TEMPERATURE 30mV OVERDRIVE MAX6715A-9A toc10 POWER-FAIL DELAY (µs) POWER-FAIL INPUT TO POWER-FAIL OUTPUT DELAY vs. TEMPERATURE 30mV OVERDRIVE MAX6715A-9A toc11 0V 0V TO RESET OUTPUT DELAY MAX6715A-9A toc1 V V/div V V/div ns/div Pin Description PIN MAX6715A/ MAX6716A MAX6717A/ MAX6718A MAX6719A/ MAX670A MAX671A/ MAX67A MAX673A/ MAX674A MAX675A/ MAX676A MAX677A MAX678A/ MAX679A/ NAME FUNCTION , 4 1 / 1 Active-Low Reset Output, Open-Drain or Push-Pull. /1 changes from high to low when or V CC drops below the selected reset thresholds, IN is below threshold, is pulled low, or the watchdog triggers a reset. /1 remains low for the reset timeout period after /V CC /IN exceed the device reset thresholds, goes low to high, or the watchdog triggers a reset. Opendrain outputs require an external pullup resistor. Push-pull outputs are referenced to. Maxim Integrated 6

7 Pin Description (continued) PIN MAX6715A/ MAX6716A MAX6717A/ MAX6718A MAX6719A/ MAX670A MAX671A/ MAX67A MAX673A/ MAX674A MAX675A/ MAX676A MAX677A MAX678A/ MAX679A/ NAME FUNCTION 5 Active-Low Reset Output, Open-Drain or Push-Pull. changes from high to low when or V CC drops below the selected reset thresholds or is pulled low. remains low for the reset timeout period after /V CC exceed the device reset thresholds or goes low to high. Open-drain outputs require an external pullup resistor. Push-pull outputs are referenced to V CC. Ground V CC Active-Low Manual-Reset Input. Internal 50kΩ pullup to. Pull low to force a reset. Reset remains active as long as is low and for the reset timeout period after goes high. Leave unconnected or connect to if unused. Secondary Supply Voltage Input. Powers the device when it is above and input for secondary reset threshold monitor. Primary Supply Voltage Input. Powers the device when it is above V CC and input for primary reset threshold monitor. Maxim Integrated 7

8 Pin Description (continued) PIN MAX6715A/ MAX6716A MAX6717A/ MAX6718A MAX6719A/ MAX670A MAX671A/ MAX67A MAX673A/ MAX674A MAX675A/ MAX676A MAX677A MAX678A/ MAX679A/ NAME FUNCTION WDI Watchdog Input. If WDI remains high or low for longer than the watchdog timeout period, the internal watchdog timer runs out and the reset output asserts for the reset timeout period. The internal watchdog timer clears whenever a reset is asserted or WDI sees a rising or falling edge. The watchdog has a long startup period (35s min) after each reset event and a short watchdog timeout period (1.1s min) after the first valid WDI transition. Leave WDI unconnected to disable the watchdog timer. The WDI unconnected-state detector uses a small 00nA current source. Therefore, do not connect WDI to anything that will source more than 50nA IN Undervoltage Reset Comparator Input. Highimpedance input for adjustable reset monitor. The reset output is asserted when IN falls below the 0.66V internal reference voltage. Set the monitored voltage reset threshold with an external resistor-divider network. Connect IN to or V CC if not used. Maxim Integrated 8

9 Pin Description (continued) PIN MAX6715A/ MAX6716A MAX6717A/ MAX6718A MAX6719A/ MAX670A MAX671A/ MAX67A MAX673A/ MAX674A MAX675A/ MAX676A MAX677A MAX678A/ MAX679A/ NAME FUNCTION 7 PFI 4 PFO Power-Fail Voltage Monitor Input. Highimpedance input for internal power-fail monitor comparator. Connect PFI to an external resistordivider network to set the power-fail threshold voltage (0.66V typical internal reference voltage). Connect to,, or V CC if not used. Active-Low Power-Fail Monitor Output, Open- Drain or Push-Pull. PFO is asserted low when PFI is less than 0.66V. PFO deasserts without a reset timeout period. Open-drain outputs require an external pullup resistor. Push-pull outputs are referenced to. 4 Active-High Reset Output, Open-Drain or Push-Pull. changes from low to high when or V CC drops below selected reset thresholds, IN is below threshold, is pulled low, or the watchdog triggers a reset. remains HIGH for the reset timeout period after /V CC /IN exceed the device reset thresholds, goes low to high, or the watchdog triggers a reset. Opendrain outputs require an external pullup resistor. Push-pull outputs are referenced to. Maxim Integrated 9

10 Detailed Description Supply Voltages The μp supervisory circuits maintain system integrity by alerting the μp to fault conditions. These ICs are optimized for systems that monitor two or three supply voltages. The output reset state is guaranteed to remain valid while either or V CC is above 0.8V. Threshold Levels Input-voltage threshold level combinations are indicated by a two-letter code in the Reset Voltage Threshold Suffix Guide (Table 1). Contact factory for availability of other voltage threshold combinations. Reset Outputs The provide an active-low reset output () and the MAX675A/ MAX676A also provide an active-high () output.,, 1, and are asserted when the voltage at either or V CC falls below the voltage threshold level, IN drops below threshold, or is pulled low. Once reset is asserted, it stays low for the reset timeout period (see Table ). If, V CC, or IN goes below the reset threshold before the reset timeout period is completed, the internal timer restarts. The MAX6715A/MAX6717A/MAX6719A/MAX671A/ MAX673A/MAX675A/MAX677A/MAX678A contain open-drain reset outputs, while the MAX6716A/ MAX6718A/MAX670A/MAX67A/MAX674A/ MAX676A/MAX679A/ contain push-pull reset outputs. The MAX677A provides two separate open-drain outputs driven by the same internal logic. Manual-Reset Input Many μp-based products require manual-reset capability, allowing the operator, a test technician, or external logic circuitry to initiate a reset. A logic-low on asserts the reset output. Reset remains asserted while is low for the reset timeout period (t RP ) after returns high. This input has an internal 50kΩ pullup resistor to and can be left unconnected if not used. can be driven with CMOS logic levels, or with open-drain/collector outputs. Connect a normally open momentary switch from to to create a manual-reset function; external debounce circuitry is not required. If is driven from long cables or if the device is used in a noisy environment, connect a 0.1μF capacitor from to to provide additional noise immunity. Adjustable Input Voltage The MAX6719A/MAX670A and MAX673A MAX677A provide an additional input to monitor a third system voltage. The threshold voltage at IN is typically 66mV. Connect a resistor-divider network to the circuit as shown in Figure 1 to establish an externally controlled threshold voltage, V EXT_TH. V EXT_TH = 66mV((R1 + R)/R) Low-leakage current at IN allows the use of largevalued resistors resulting in reduced power consumption of the system. Watchdog Input The watchdog monitors μp activity through the watchdog input (WDI). To use the watchdog function, connect WDI to a bus line or μp I/O line. When WDI remains high or low for longer than the watchdog timeout period, the reset output asserts. The MAX671A MAX679A/ include a dualmode watchdog timer to monitor μp activity. The flexible timeout architecture provides a long period initial watchdog mode, allowing complicated systems to complete lengthy boots, and a short period normal watchdog mode, allowing the supervisor to provide quick alerts when processor activity fails. After each reset event (V CC powerup/brownout, manual reset, or watchdog reset), there is a long initial watchdog period of 35s minimum. The long watchdog period mode provides an extended time for the system to power-up and fully initialize all μp and system components before assuming responsibility for routine watchdog updates. V EXT_TH R1 R IN Figure 1. Monitoring a Third Voltage MAX6719A/ MAX670A/ MAX673A MAX677A Maxim Integrated 10

11 The normal watchdog timeout period (1.1s min) begins after the first transition on WDI before the conclusion of the long initial watchdog period (Figure ). During the normal operating mode, the supervisor will issue a reset pulse for the reset timeout period if the μp does not update the WDI with a valid transition (high-to-low or lowto-high) within the standard timeout period (1.1s min). Leave WDI unconnected to disable the watchdog timer. The WDI unconnected-state detector uses a small (00nA typ) current source. Therefore, do not connect WDI to anything that will source more than 50nA. Power-Fail Comparator PFI is the noninverting input to a comparator. If PFI is less than V PFI (66.5mV), PFO goes low. Common uses for the power-fail comparator include monitoring preregulated input of the power supply (such as a battery) or providing an early power-fail warning so software can conduct an orderly system shutdown. It can also be used to monitor supplies other than or V CC by setting the powerfail threshold with a resistor-divider, as shown in Figure 3. PFI is the input to the power-fail comparator. The typical comparator delay is μs from PFI to PFO. Connect PFI to ground of if unused. Ensuring a Valid Reset Output Down to V CC = 0V The are guaranteed to operate properly down to V CC = 0.8V. In applications that require valid reset levels down to V CC = 0V, use a pulldown resistor at to ground. The resistor value used is not critical, but it must be large enough not to load the reset output when V CC is above the reset threshold. For most applications, 100kΩ is adequate. This configuration does not work for the open-drain outputs of the MAX6715A/MAX6717A/MAX6719A/MAX671A/ MAX673A/MAX675A/MAX677A/MAX678A. For push-pull, active-high output connect the external resistor as a pullup from to VCC1. V IN A) R1 R PFI MAX678A/ MAX679A/ PFO V TRIP = V PFI ( ) R1 + R R B) V CC WDI V TH t WDI-NORMAL 1.1s MAX t WDI-STARTUP 35s MAX 1.1s MAX V CC R1 R PFI MAX678A/ MAX679A/ PFO ( ) V TRIP = R (V PFI ) 1 1 R1 + R - V [ CC R1 ] V PFI = 66.5mV t RP V IN Figure. Normal Watchdog Startup Sequence Figure 3. Using Power-Fail Input to Monitor an Additional Power-Supply a) V IN is Positive b) V IN is Negative Maxim Integrated 11

12 Applications Information Interfacing to μps with Bidirectional Reset Pins Most μps with bidirectional reset pins can interface directly to open-drain output options. Systems simultaneously requiring a push-pull output and a bidirectional reset interface can be in logic contention. To prevent contention, connect a 4.7kΩ resistor between and the μp s reset I/O port, as shown in Figure 4. Adding Hysteresis to the Power-Fail Comparator The power-fail comparator has a typical input hysteresis of 3mV. This is sufficient for most applications where a power-supply line is being monitored through an external voltage-divider (see the Power-Fail Comparator section). If additional noise margin is desired, connect a resistor between PFO and PFI as shown in Figure 5. Select the values of R1, R, and R3 so PFI sees V PFI (66mV) when V EXT falls to its power-fail trip point (V FAIL ) and when V IN rises to its power-good trip point (V GOOD ). The hysteresis window extends between the specified V FAIL and V GOOD thresholds. R3 adds the additional hysteresis by sinking current from the R1/R divider network when PFO is logic-low and sourcing current into the network when PFO is logic-high. R3 is typically an order of magnitude greater than R1 or R. The current through R should be at least.5μa to ensure that the 100nA (max) PFI input current does not significantly shift the trip points. Therefore, R < V PFI /10μA < 6kΩ for most applications. R3 will provide additional hysteresis for PFO push-pull (V OH = ) or open-drain (V OH = V PULLUP ) applications. Monitoring an Additional Power Supply These μp supervisors can monitor either positive or negative supplies using a resistor voltage-divider to PFI. PFO can be used to generate an interrupt to the μp or cause reset to assert (Figure 3). Monitoring a Negative Voltage The power-fail comparator can be used to monitor a negative supply voltage using the circuit shown in Figure 3. When the negative supply is valid, PFO is low. When the negative supply voltage drops, PFO goes high. The circuit s accuracy is affected by the PFI threshold tolerance, V CC, R1, and R. Negative-Going V CC Transients The supervisors are relatively immune to short-duration negative-going V CC transients (glitches). It is usually undesirable to reset the μp when V CC experiences only small glitches. The Typical Operating Characteristics show Maximum Transient Duration vs. Reset Threshold Overdrive, for which reset pulses are not generated. The graph was produced using negative-going V CC pulses, starting above V TH and ending below the reset threshold by the V CC RESET TO OTHER SYSTEM COMPONENTS R3 V CC MAX6715A MAX679A/ 4.7kΩ RESET µp A V EXT R1 R MAX679A PFI PFO V IN PFO V GOOD V FAIL V GOOD = DESIRED V EXT GOOD VOLTAGE THRESHOLD V FAIL = DESIRED V EXT FAIL VOLTAGE THRESHOLD V OH = (FOR PUSH-PULL PFO) R = 50kΩ (FOR > 10µA R CURRENT) R1 = R ((V GOOD - V PFI ) - (V PFI )(V GOOD - V FAIL )/V OH )/V PFI R3 = (R1 x V OH )/(V GOOD - V FAIL ) Figure 4. Interfacing to μps with Bidirectional Reset I/O Figure 5. Adding Hysteresis to Power-Fail for Push-Pull PFO Maxim Integrated 1

13 magnitude indicated (reset threshold overdrive). The graph shows the maximum pulse width that a negativegoing V CC transient may typically have without causing a reset pulse to be issued. As the amplitude of the transient increases (i.e., goes farther below the reset threshold), the maximum allowable pulse width decreases. A 0.1μF bypass capacitor mounted close to the V CC pin provides additional transient immunity. Watchdog Software Considerations Setting and resetting the watchdog input at different points in the program, rather than pulsing the watchdog input high-low-high or low-high-low, helps the watchdog timer to closely monitor software execution. This technique avoids a stuck loop where the watchdog timer continues to be reset within the loop, keeping the watchdog from timing out. Figure 6 shows an example flow diagram where the I/O driving the watchdog input is set high at the beginning of the program, set low at the beginning of every subroutine or loop, then set high again when the program returns to the beginning. If the program should hang in any subroutine, the I/O is continually set low and the watchdog timer is allowed to time out, causing a reset or interrupt to be issued. SUBROUTINE COMPLETED START SET WDI HIGH PROGRAM CODE SUBROUTINE OR PROGRAM LOOP SET WDI LOW RETURN Figure 6. Watchdog Flow Diagram HANG IN SUBROUTINE Maxim Integrated 13

14 Functional Diagram PULLUP V CC V CC V REF RESET TIMEOUT PERIOD RESET OUTPUT DRIVER IN/PFI PFO V REF WATCHDOG TIMER WDI V REF/ Maxim Integrated 14

15 Selector Guide PART NUMBER NUMBER OF VOLTAGE MONITORS OPEN- DRAIN RESET OPEN- DRAIN RESET PUSH- PULL RESET PUSH- PULL RESET MANUAL RESET WATCH- DOG INPUT POWER-FAIL INPUT/ OUTPUT MAX6715A MAX6716A MAX6717A 1 MAX6718A 1 MAX6719A 3 1 MAX670A 3 1 MAX671A 1 MAX67A 1 MAX673A 3 1 MAX674A 3 1 MAX675A MAX676A MAX677A 3 MAX678A 1 (open drain) MAX679A 1 (push-pull) 1 (open drain) Ordering Information PART TEMP RANGE PIN-PACKAGE MAX6715AUT D_+T -40 C to +15 C 6 SOT3 MAX6716AUT D_+T -40 C to +15 C 6 SOT3 MAX6717AUK D_+T -40 C to +15 C 5 SOT3 MAX6718AUK D_+T -40 C to +15 C 5 SOT3 MAX6719AUT D_+T -40 C to +15 C 6 SOT3 MAX6719AUT D_/V+T* -40 C to +15 C 6 SOT3 MAX6719AUTTWD1/V+T -40 C to +15 C 6 SOT3 MAX670AUT D_+T -40 C to +15 C 6 SOT3 MAX671AUT D_+T -40 C to +15 C 6 SOT3 PART TEMP RANGE PIN-PACKAGE MAX67AUT D_+T -40 C to +15 C 6 SOT3 MAX673AUT D_+T -40 C to +15 C 6 SOT3 MAX674AUT D_+T -40 C to +15 C 6 SOT3 MAX675AKA D_+T -40 C to +15 C 8 SOT3 MAX676AKA D_+T -40 C to +15 C 8 SOT3 MAX677AKA D_+T -40 C to +15 C 8 SOT3 MAX678AKA D_+T -40 C to +15 C 8 SOT3 MAX679AKA D_+T -40 C to +15 C 8 SOT3 KA D_+T -40 C to +15 C 8 SOT3 +Denotes a lead(pb)-free/rohs-compliant package. T = Tape and reel. Note: The first are placeholders for the threshold voltage levels of the devices. Desired threshold levels are set by the part number suffix found in the Reset Voltage Threshold Suffix Guide. The _ after the D is a placeholder for the reset timeout delay time. Desired delay time is set using the timeout period suffix found in the Reset Timeout Period Suffix Guide. For example, the MAX6716AUTLTD3-T is a dual-voltage supervisor V TH1 = 4.65V, V TH = 3.075V, and 10ms (typ) timeout period. Maxim Integrated 15

16 Table 1. Reset Voltage Threshold Suffix Guide** PART NUMBER SUFFIX ( ) VCC1 NOMINAL VOLTAGE THRESHOLD (V) VCC NOMINAL VOLTAGE THRESHOLD (V) LT MS TZ SY RY TW SV RV TI SH RH TG SF RF TE SD RD ZW YV ZI YH ZG YF ZE YD WI VH WG VF WE VD Table. Reset Timeout Period Suffix Guide TIMEOUT ACTIVE TIMEOUT PERIOD PERIOD SUFFIX MIN (ms) MAX (ms) D D D D D D D D D7 and D8 timeout periods are only available for the. Note: Standard versions are shown in bold and are available in a D3 timeout option only. Standard versions require 500-pieceorder increments and are typically held in sample stock. There is a 10,000 order increment on nonstandard versions. Other threshold voltages may be available; contact factory for availability. Maxim Integrated 16

17 Pin Configurations TOP VIEW MAX6715A/ MAX6716A 5 MAX6717A/ MAX6718A MAX6719A/ MAX670A 5 IN 3 4 V CC 3 4 V CC 3 4 V CC SOT3 SOT3 SOT MAX671A/ MAX67A 5 WDI MAX673A/ MAX674A 5 IN WDI 3 MAX675A/ MAX676A 7 6 IN V CC 3 4 V CC WDI 3 4 V CC 4 5 SOT3 SOT3 SOT WDI 3 4 MAX677A IN V CC WDI PFO 3 4 MAX678A/ MAX679A/ PFI V CC SOT3 SOT3 Chip Information PROCESS: BiCMOS Package Information For the latest package outline information and land patterns (footprints), go to Note that a +, #, or - in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 5 SOT3 U SOT3 U SOT3 K8SN Maxim Integrated 17

18 Revision History REVISION NUMBER REVISION DATE DESCRIPTION PAGES CHANGED 0 4/06 Initial release 1 7/06 Updated Ordering Information 1, 15 6/08 Added the to Ordering Information, Electrical Characteristics, Pin Description, Detailed Description, Figures 4 and 5, Selector Guide, Table, Pin Configurations 1,, 6 11, 1, /08 Updated Selector Guide /14 Added automotive part to the Ordering Information table /17 Added AEC qualfication statement to Benefits and Features section and updated Ordering Information table 1, 17 For pricing, delivery, and ordering information, please contact Maxim Direct at , or visit Maxim Integrated s website at Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. 017 Maxim Integrated Products, Inc. 18

Single/Dual/Triple-Voltage μp Supervisory Circuits with Independent Watchdog Output

Single/Dual/Triple-Voltage μp Supervisory Circuits with Independent Watchdog Output General Description The MAX6730 MAX6735 single/dual/triple-voltage microprocessor (μp) supervisors feature a watchdog timer and manual reset capability. The MAX6730 MAX6735 offer factory-set reset thresholds