������� ������� semiconductor technical data universal voltage monitors pin connections order this document by mc34161/d p suffix plastic package case 626 d suffix plastic package case 751 (so8) 8 1 1 8 v ref input 1 input 2 gnd v cc mode select output 1 output 2 1 2 3 4 8 7 6 5 (top view) ordering information device operating temperature range package mc34161d t a = 0 to +70 c t a = 40 to +85 c so8 mc34161p plastic dip mc33161d so8 MC33161P plastic dip 1 motorola analog ic device data ��
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���� the mc34161/mc33161 are universal voltage monitors intended for use in a wide variety of voltage sensing applications. these devices offer the circuit designer an economical solution for positive and negative voltage detection. the circuit consists of two comparator channels each with hysteresis, a unique mode select input for channel programming, a pinned out 2.54 v reference, and two open collector outputs capable of sinking in excess of 10 ma. each comparator channel can be configured as either inverting or noninverting by the mode select input. this allows over, under, and window detection of positive and negative voltages. the minimum supply voltage needed for these devices to be fully functional is 2.0 v for positive voltage sensing and 4.0 v for negative voltage sensing. applications include direct monitoring of positive and negative voltages used in appliance, automotive, consumer, and industrial equipment. ? unique mode select input allows channel programming ? over, under, and window voltage detection ? positive and negative voltage detection ? fully functional at 2.0 v for positve voltage sensing and 4.0 v for negative voltage sensing ? pinned out 2.54 v reference with current limit protection ? low standby current ? open collector outputs for enhanced device flexibility simplified block diagram (positive voltage window detector application) v cc 6 1 7 v s 2 3 + 1.27v + 1.27v + 2.8v + 0.6v + 8 5 2.54v reference + + + 4 ? motorola, inc. 1998 rev 1.1
mc34161 mc33161 2 motorola analog ic device data maximum ratings rating symbol value unit power supply input voltage v cc 40 v comparator input voltage range v in 1.0 to +40 v comparator output sink current (pins 5 and 6) (note 1) i sink 20 ma comparator output voltage v out 40 v power dissipation and thermal characteristics (note 1) p suffix, plastic package, case 626 maximum power dissipation @ t a = 70 c thermal resistance, junctiontoair d suffix, plastic package, case 751 maximum power dissipation @ t a = 70 c thermal resistance, junctiontoair p d r q ja p d r q ja 800 100 450 178 mw c/w mw c/w operating junction temperature t j +150 c operating ambient temperature (note 3) mc34161 mc33161 t a 0 to +70 40 to +85 c storage temperature range t stg 55 to +150 c electrical characteristics (v cc = 5.0 v, for typical values t a = 25 c, for min/max values t a is the operating ambient temperature range that applies [notes 2 and 3], unless otherwise noted.) characteristics symbol min typ max unit comparator inputs threshold voltage, v in increasing (t a = 25 c) threshold voltage, v in increasing (t a = t min to t max ) v th 1.245 1.235 1.27 1.295 1.295 v threshold voltage variation (v cc = 2.0 v to 40 v) d v th 7.0 15 mv threshold hysteresis, v in decreasing v h 15 25 35 mv threshold difference |v th1 v th2 | v d 1.0 15 mv reference to threshold difference (v ref v in1 ), (v ref v in2 ) v rtd 1.20 1.27 1.32 v input bias current (v in = 1.0 v) input bias current (v in = 1.5 v) i ib 40 85 200 400 na mode select input mode select threshold voltage (figure 5) channel 1 mode select threshold voltage (figure 5) channel 2 v th(ch 1) v th(ch 2) v ref +0.15 0.3 v ref +0.23 0.63 v ref +0.30 0.9 v comparator outputs output sink saturation voltage (i sink = 2.0 ma) output sink saturation voltage (i sink = 10 ma) output sink saturation voltage (i sink = 0.25 ma, v cc = 1.0 v) v ol 0.05 0.22 0.02 0.3 0.6 0.2 v offstate leakage current (v oh = 40 v) i oh 0 1.0 m a reference output output voltage (i o = 0 ma, t a = 25 c) v ref 2.48 2.54 2.60 v load regulation (i o = 0 ma to 2.0 ma) reg load 0.6 15 mv line regulation (v cc = 4.0 v to 40 v) reg line 5.0 15 mv total output variation over line, load, and temperature d v ref 2.45 2.60 v short circuit current i sc 8.5 30 ma total device power supply current (v mode , v in1 , v in2 = gnd) (v cc = 5.0 v) power supply current (v mode , v in 1, v in 2 = gd) (v cc = 40 v) i cc 450 560 700 900 m a operating voltage range (positive sensing) operating voltage range (negative sensing) v cc 2.0 4.0 40 40 v notes: 1. maximum package power dissipation must be observed. 2. low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. 3. t low =0 c for mc34161 t high = +70 c for mc34161 40 c for mc33161 +85 c for mc33161
mc34161 mc33161 3 motorola analog ic device data v out , channel output voltage (v) t a = 25 c t a = 40 c t a = 40 c t a = 85 c t a = 85 c 1.0 3.0 0 0.5 1.5 2.5 2.0 3.5 channel 2 threshold channel 1 threshold v cc = 5.0 v r l = 10 k to v cc v mode , mode select input voltage (v) t a = 25 c figure 1. comparator input threshold voltage v cc = 5.0 v r l = 10 k to v cc t a = 25 c v t a = 40 c t a = 85 c t a = 25 c 1.22 1.28 1.23 1.24 1.25 1.26 1.27 1.29 v in , input voltage (v) out , output voltage (v) t a = 85 c t a = 25 c t a = 40 c figure 2. comparator input bias current versus input voltage 4.0 6.0 0 2.0 1 2 3 4 1. v mode = gnd, output falling 2. v mode = v cc , output rising 3. v mode = v cc , output falling 4. v mode = gnd, output rising v cc = 5.0 v t a = 25 c 8.0 10 , output propagation delay time (ns) phl t percent overdrive (%) figure 3. output propagation delay time versus percent overdrive figure 4. output voltage versus supply voltage i , input bias current (na) ib v cc = 5.0 v v mode = gnd t a = 25 c 1.0 3.0 2.0 0 4.0 5.0 v in , input voltage (v) figure 5. mode select thresholds 0 2.0 4.0 6.0 8.0 v cc , supply voltage (v) v out , output voltage (v) t a = 40 c t a = 25 c t a = 85 c figure 6. mode select input current versus input voltage 1.0 3.0 2.0 0 4.0 5.0 v cc = 5.0 v t a = 25 c v mode , mode select input voltage (v) 2.0 1.0 6.0 5.0 0 4.0 3.0 2.0 1.0 6.0 5.0 0 4.0 3.0 3600 3000 2400 1800 1200 600 500 400 300 200 100 0 8.0 6.0 4.0 2.0 0 40 35 30 25 20 15 10 5.0 0 , mode select input current ( a) m mode i undervoltage detector programmed to trip at 4.5 v r 1 = 1.8 k, r 2 = 4.7 k r l = 10 k to v cc refer to figure 16
mc34161 mc33161 4 motorola analog ic device data v out , output saturation voltage (v) ref v , reference voltage (v) figure 7. reference voltage versus supply voltage v mode = gnd t a = 25 c 10 30 20 40 v cc , supply voltage (v) figure 8. reference voltage versus ambient temperature , reference voltage change (mv) ref v 1.0 0 i ref , reference source current (ma) 2.0 3.0 4.0 5.0 6.0 7.0 8.0 t a = 85 c t a = 25 c v cc = 5.0 v v mode = gnd t a = 40 c figure 9. reference voltage change versus source current 10 0 v cc , supply voltage (v) 20 30 40 , supply current (ma) cc i v mode = gnd pins 2, 3 = 1.5 v v mode = v ref pin 1 = 1.5 v pin 2 = gnd i cc measured at pin 8 t a = 25 c v mode = v cc pins 2, 3 = gnd figure 10. output saturation voltage versus output sink current figure 11. supply current versus supply voltage figure 12. supply current versus output sink current , reference output voltage (v) ref v v cc = 5.0 v v mode = gnd t a , ambient temperature ( c) 55 25 0 25 50 75 100 125 v ref min = 2.48 v v ref typ = 2.54 v v ref max = 2.60 v 4.0 0 i out , output sink current (ma) 8.0 12 16 t a = 85 c t a = 25 c t a = 40 c v cc = 5.0 v v mode = gnd v cc = 5.0 v v mode = gnd t a = 25 c 4.0 0 i out , output sink current (ma) 8.0 12 16 , input supply current (ma) cc i 2.8 2.4 2.0 1.6 1.2 0.8 0.4 0 0 0 2.0 4.0 6.0 8.0 10 0.8 0.6 0 0.4 0.2 2.610 2.578 2.546 2.514 2.482 2.450 0.1 0.5 0.4 0 0.3 0.2 1.6 1.2 0 0.8 0.4
mc34161 mc33161 5 motorola analog ic device data figure 13. mc34161 representative block diagram 8 v cc 2.54v reference + 1.27v + 2.8v + + + 1.27v + 0.6v + + 4 1 v ref 6 5 output 1 output 2 mode select 7 input 1 2 input 2 3 gnd channel 1 channel 2 figure 14. truth table mode select pin 7 input 1 pin 2 output 1 pin 6 input 2 pin 3 output 2 pin 5 comments gnd 0 1 0 1 0 1 0 1 channels 1 & 2: noninverting v ref 0 1 0 1 0 1 1 0 channel 1: noninverting channel 2: inverting v cc (>2.0 v) 0 1 1 0 0 1 1 0 channels 1 & 2: inverting
mc34161 mc33161 6 motorola analog ic device data functional description introduction to be competitive in today's electronic equipment market, new circuits must be designed to increase system reliability with minimal incremental cost. the circuit designer can take a significant step toward attaining these goals by implementing economical circuitry that continuously monitors critical circuit voltages and provides a fault signal in the event of an outoftolerance condition. the mc34161, mc33161 series are universal voltage monitors intended for use in a wide variety of voltage sensing applications. the main objectives of this series was to configure a device that can be used in as many voltage sensing applications as possible while minimizing cost. the flexibility objective is achieved by the utilization of a unique mode select input that is used in conjunction with traditional circuit building blocks. the cost objective is achieved by processing the device on a standard bipolar analog flow, and by limiting the package to eight pins. the device consists of two comparator channels each with hysteresis, a mode select input for channel programming, a pinned out reference, and two open collector outputs. each comparator channel can be configured as either inverting or noninverting by the mode select input. this allows a single device to perform over, under, and window detection of positive and negative voltages. a detailed description of each section of the device is given below with the representative block diagram shown in figure 13. input comparators the input comparators of each channel are identical, each having an upper threshold voltage of 1.27 v 2.0% with 25 mv of hysteresis. the hysteresis is provided to enhance output switching by preventing oscillations as the comparator thresholds are crossed. the comparators have an input bias current of 60 na at their threshold which approximates a 21.2 m w resistor to ground. this high impedance minimizes loading of the external voltage divider for well defined trip points. for all positive voltage sensing applications, both comparator channels are fully functional at a v cc of 2.0 v. in order to provide enhanced device ruggedness for hostile industrial environments, additional circuitry was designed into the inputs to prevent device latchup as well as to suppress electrostatic discharges (esd). reference the 2.54 v reference is pinned out to provide a means for the input comparators to sense negative voltages, as well as a means to program the mode select input for window detection applications. the reference is capable of sourcing in excess of 2.0 ma output current and has builtin short circuit protection. the output voltage has a guaranteed tolerance of 2.4% at room temperature. the 2.54 v reference is derived by gaining up the internal 1.27 v reference by a factor of two. with a power supply voltage of 4.0 v, the 2.54 v reference is in full regulation, allowing the device to accurately sense negative voltages. mode select circuit the key feature that allows this device to be flexible is the mode select input. this input allows the user to program each of the channels for various types of voltage sensing applications. figure 14 shows that the mode select input has three defined states. these states determine whether channel 1 and/or channel 2 operate in the inverting or noninverting mode. the mode select thresholds are shown in figure 5. the input circuitry forms a tristate switch with thresholds at 0.63 v and v ref + 0.23 v. the mode select input current is 10 m a when connected to the reference output, and 42 m a when connected to a v cc of 5.0 v, refer to figure 6. output stage the output stage uses a positive feedback base boost circuit for enhanced sink saturation, while maintaining a relatively low device standby current. figure 10 shows that the sink saturation voltage is about 0.2 v at 8.0 ma over temperature. by combining the low output saturation characteristics with low voltage comparator operation, this device is capable of sensing positive voltages at a v cc of 1.0 v. these characteristics are important in undervoltage sensing applications where the output must stay in a low state as v cc approaches ground. figure 4 shows the output voltage versus supply voltage in an undervoltage sensing application. note that as v cc drops below the programmed 4.5 v trip point, the output stays in a well defined active low state until v cc drops below 1.0 v. applications the following circuit figures illustrate the flexibility of this device. included are voltage sensing applications for over, under, and window detectors, as well as three unique configurations. many of the voltage detection circuits are shown with the open collector outputs of each channel connected together driving a light emitting diode (led). this `ored' connection is shown for ease of explanation and it is only required for window detection applications. note that many of the voltage detection circuits are shown with a dashed line output connection. this connection gives the inverse function of the solid line connection. for example, the solid line output connection of figure 15 has the led `on' when input voltage v s is above trip voltage v 2 , for overvoltage detection. the dashed line output connection has the led `on' when v s is below trip voltage v 2 , for undervoltage detection.
mc34161 mc33161 7 motorola analog ic device data the above figure shows the mc34161 configured as a dual positive overvoltage detector. as the input voltage increases from ground, the led will turn `on' when v s1 or v s2 exceeds v 2 . with the dashed line output connection, the circuit becomes a dual positive undervoltage detector. as the input voltage decreases from the peak towards ground, the led will turn `on' when v s1 or v s2 falls below v 1 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: v 1 � (v th � v h ) � r 2 r 1 � 1 � v 2 � v th � r 2 r 1 � 1 � r 2 r 1 � v 1 v th � v h � 1 r 2 r 1 � v 2 v th � 1 figure 15. dual postive overvoltage detector 8 + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 v s2 r 1 r 2 r 2 r 1 v cc input v s output voltage pins 5, 6 v 2 v 1 gnd v cc led `on' v hys gnd v s1 the above figure shows the mc34161 configured as a dual positive undervoltage detector. as the input voltage decreases towards ground, the led will turn `on' when v s1 or v s2 falls below v 1 . with the dashed line output connection, the circuit becomes a dual positive overvoltage detector. as the input voltage increases from ground, the led will turn `on' when v s1 or v s2 exceeds v 2 . v 1 � (v th � v h ) � r 2 r 1 � 1 � v 2 � v th � r 2 r 1 � 1 � r 2 r 1 � v 1 v th � v h � 1 r 2 r 1 � v 2 v th � 1 for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 16. dual postive undervoltage detector v s1 + 1.27v + 1.27v + 2.8v + 0.6v + 8 + + + 4 1 7 2 3 5 6 v s2 2.54v reference v cc r 1 r 2 r 2 r 1 v hys input v s output voltage pins 5, 6 v 2 v 1 gnd v cc led `on' gnd
mc34161 mc33161 8 motorola analog ic device data the above figure shows the mc34161 configured as a dual negative overvoltage detector. as the input voltage increases from ground, the led will turn `on' when v s1 or v s2 exceeds v 2 . with the dashed line output connection, the circuit becomes a dual negative undervoltage detector. as the input voltage decreases from the peak towards ground, the led will turn `on' when v s1 or v s2 falls below v 1 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 17. dual negative overvoltage detector v 1 � r 1 r 2 (v th � v ref ) � v th v 2 � r 1 r 2 (v th � v h � v ref ) � v th � v h r 1 r 2 � v 1 � v th v th � v ref r 1 r 2 � v 2 � v th � v h v th � v h � v ref + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 r1 v s1 r1 v s2 r 2 r 2 8 v cc input v s output voltage pins 5, 6 gnd v 1 v 2 v cc led `on' v hys gnd the above figure shows the mc34161 configured as a dual negative undervoltage detector. as the input voltage decreases towards ground, the led will turn `on' when v s1 or v s2 falls below v 1 . with the dashed line output connection, the circuit becomes a dual negative overvoltage detector. as the input voltage increases from ground, the led will turn `on' when v s1 or v s2 exceeds v 2 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 18. dual negative undervoltage detector v 1 � r 1 r 2 (v th � v ref ) � v th v 2 � r 1 r 2 (v th � v h � v ref ) � v th � v h r 1 r 2 � v 1 � v th v th � v ref r 1 r 2 � v 2 � v th � v h v th � v h � v ref + 1.27v + 1.27v + 2.8v + 0.6v + 8 + + + 4 1 7 2 3 5 6 r1 v s1 r1 v s2 2.54v reference r 2 r 2 v cc v hys input v s output voltage pins 5, 6 gnd v 1 v 2 v cc led `on' gnd
mc34161 mc33161 9 motorola analog ic device data the above figure shows the mc34161 configured as a positive voltage window detector. this is accomplished by connecting channel 1 as an undervoltage detector, and channel 2 as an overvoltage detector. when the input voltage v s falls out of the window established by v 1 and v 4 , the led will turn `on'. as the input voltage falls within the window, v s increasing from ground and exceeding v 2 , or v s decreasing from the peak towards ground and falling below v 3 , the led will turn `off'. with the dashed line output connection, the led will turn `on' when the input voltage v s is within the window. for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 19. positive voltage window detector v 1 � (v th1 � v h1 ) � r 3 r 1 � r 2 � 1 � v 3 � (v th2 � v h2 ) � r 2 � r 3 r 1 � 1 � v 2 � v th1 � r 3 r 1 � r 2 � 1 � v 4 � v th2 � r 2 � r 3 r 1 � 1 � r 2 r 1 � v 3 (v th2 � v h2 ) v 1 (v th1 � v h1 ) � 1 r 3 r 1 � v 3 (v 1 � v th1 � v h1 ) v 1 (v th2 � v h2 ) r 2 r 1 � v 4 xv th2 v 2 xv th1 � 1 r 3 r 1 � v 4 (v 2 � v th1 ) v 2 xv th2 + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 v s r 3 r 1 r 2 8 v cc output voltage pins 5, 6 gnd ch2 ch1 led `on' v hys2 v hys1 led `on' `off' led `off' `on' v 4 v 3 v 2 v 1 v cc gnd input v s the above figure shows the mc34161 configured as a negative voltage window detector. when the input voltage v s falls out of the window established by v 1 and v 4 , the led will turn `on'. as the input voltage falls within the window, v s increasing from ground and exceeding v 2 , or v s decreasing from the peak towards ground and falling below v 3 , the led will turn `off'. with the dashed line output connection, the led will turn `on' when the input voltage v s is within the window. for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 20. negative voltage window detector v 1 � r 1 (v th2 � v ref ) r 2 � r 3 � v th2 v 2 � r 1 (v th2 � v h2 � v ref ) r 2 � r 3 � v th2 � v h2 v 3 � (r 1 � r 2 )(v th1 � v ref ) r 3 � v th1 v 4 � (r 1 � r 2 )(v th1 � v h1 � v ref ) r 3 � v th1 � v h1 r 1 r 2 � r 3 � v 1 � v th2 v th2 � v ref r 1 r 2 � r 3 � v 2 � v th2 � v h2 v th2 � v h2 � v ref r 3 r 1 � r 2 � v th1 � v ref v 3 � v th1 r 3 r 1 � r 2 � v th1 � v h1 � v ref v 4 � v h1 � v th1 + 1.27v + 1.27v + 2.8v + 0.6v + + + + 4 1 7 2 3 5 6 2.54v reference r 3 r 1 r 2 v s 8 v cc output voltage pins 5, 6 gnd ch2 ch1 v 1 v 2 v 3 v 4 v cc gnd input v s led `on' led `on' `off' led `off' `on' v hys1 v hys2
mc34161 mc33161 10 motorola analog ic device data the above figure shows the mc34161 configured as a positive and negative overvoltage detector. as the input voltage increases from ground, the led will turn `on' when either v s1 exceeds v 2 , or v s2 exceeds v 4 . with the dashed line output connection, the circuit becomes a positive and negative undervoltage detector. as the input voltage decreases from the peak towards ground, the led will turn `on' when either v s2 falls below v 3 , or v s1 falls below v 1 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 21. positive and negative overvoltage detector v 1 � r 3 r 4 (v th1 � v ref ) � v th1 v 2 � r 3 r 4 (v th1 � v h1 � v ref ) � v th1 � v h1 v 3 � (v th2 � v h2 ) � r 2 r 1 � 1 � v 4 � v th2 � r 2 r 1 � 1 � r 3 r 4 � (v 1 � v th1 ) (v th1 � v ref ) r 3 r 4 � (v 2 � v th1 � v h1 ) (v th1 � v h1 � v ref ) r 2 r 1 � v 4 v th2 � 1 r 2 r 1 � v 3 v th2 � v h2 � 1 + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 r 4 r 3 v s1 v s2 r 1 r2 8 v cc output voltage pins 5, 6 gnd led `on' v hys2 v hys1 v cc gnd input v s1 v 4 v 3 v 1 v 2 input v s2 the above figure shows the mc34161 configured as a positive and negative undervoltage detector. as the input voltage decreases toward ground, the led will turn `on' when either v s1 falls below v 1 , or v s2 falls below v 3 . with the dashed line output connection, the circuit becomes a positive and negative overvoltage detector. as the input voltage increases from the ground, the led will turn `on' when either v s1 exceeds v 2 , or v s1 exceeds v 1 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 22. positive and negative undervoltage detector v 1 � (v th1 � v h1 ) � r 4 r 3 � 1 � v 2 � v th1 � r 4 r 3 � 1 � v 3 � r 1 r 2 (v th � v ref ) � v th2 v 4 � r 1 r 2 (v th � v h2 � v ref ) � v th2 � v h2 r 4 r 3 � v 2 v th1 � 1 r 4 r 3 � v 1 v th1 � v h1 � 1 r 1 r 2 � v 4 � v h2 � v th2 v th2 � v h2 � v ref r 1 r 2 � v 3 � v th2 v th2 � v ref + 1.27v + 1.27v + 2.8v + 0.6v + + + + 4 1 7 2 3 5 6 2.54v reference 8 v cc r 3 v s1 r 4 r 1 r 2 v s2 v 2 v 1 v 3 v 4 gnd v cc gnd output voltage pins 5, 6 input v s2 input v s1 led `on' v hys2 v hys1
mc34161 mc33161 11 motorola analog ic device data the above figure shows the mc34161 configured as an overvoltage detector with an audio alarm. channel 1 monitors input voltage v s while channel 2 is connected as a simple rc oscillator. as the input voltage increases from ground, the output of channel 1 allows the oscillator to turn `on' when v s exceeds v 2 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 23. overvoltage detector with audio alarm v 1 � (v th � v h ) � r 2 r 1 � 1 � v 2 � v th � r 2 r 1 � 1 � r 2 r 1 � v 1 v th � v h � 1 r 2 r 1 � v 2 v th � 1 + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 8 v cc r a v s r 1 r 2 r b c t v 2 v 1 input v s output voltage pins 5, 6 gnd v cc gnd osc `on' v hys piezo the above figure shows the mc34161 configured as a microprocessor reset with a time delay. channel 2 monitors input voltage v s while channel 1 performs the time delay function. as the input voltage decreases towards ground, the output of channel 2 quickly discharges c dly when v s falls below v 1 . as the input voltage increases from ground, the output of channel 2 allows r dly to charge c dly when v s exceeds v 2 . for known resistor values, the voltage trip points are: for a specific trip voltage, the required resistor ratio is: figure 24. microprocessor reset with time delay v 1 � (v th � v h ) � r 2 r 1 � 1 � v 2 � v th � r 2 r 1 � 1 � for known r dly c dly values, the reset time delay is: r 2 r 1 � v 1 v th � v h � 1 r 2 r 1 � v 2 v th � 1 + 1.27v + 1.27v + 2.8v + 0.6v + + + + 4 1 7 2 3 5 6 2.54v reference 8 v cc r 3 r dly v s r 1 r 2 c dly input v s output voltage pin 6 v 2 v 1 gnd v cc gnd v cc gnd v hys t dly reset led `on' output voltage pin 5 1 1 v th v cc t dly = r dly c dly in
mc34161 mc33161 12 motorola analog ic device data t figure 25. automatic ac line voltage selector + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 8 10k + 220 250v 10k 1.2k 100k 1.6m + 10 10k 3w mr506 3.0a input 92 vac to 276 vac 1n 4742 b+ rtn + 47 + 220 250v 75k 75k mac 228a6fp the above circuit shows the mc34161 configured as an automatic line voltage selector. the ic controls the triac, enabling the circuit to function as a fullwave voltage doubler or a fullwave bridge. channel 1 senses the negative half cycles of the ac line voltage. if the line voltage is less than150 v, the circuit will switch from bridge mode to voltage doubling mode after a preset time delay. the delay is controlled by the 100 k w resistor and the 10 m f capacitor. if the line voltage is greater than 150 v, the circuit will immediately return to fullwave bridge mode.
mc34161 mc33161 13 motorola analog ic device data figure 26. stepdown converter + 1.27v + 1.27v + 2.8v + 0.6v + 2.54v reference + + + 4 1 7 2 3 5 6 8 0.005 470 0.01 1.8k + 330 v in 12v 4.7k 1.6k 0.01 47k 1n5819 mps750 470 m h + 1000 v o 5.0v/250ma test conditions results line regulation v in = 9.5 v to 24 v, i o = 250 ma 40 mv = 0.1% load regulation v in = 12 v, i o = 0.25 ma to 250 ma 2.0 mv = 0.2% output ripple v in = 12 v, i o = 250 ma 50 mvpp efficiency v in = 12 v, i o = 250 ma 87.8% the above figure shows the mc34161 configured as a stepdown converter. channel 1 monitors the output voltage while channel 2 performs the oscillator function. upon initial powerup, the converters output voltage will be below nominal, and the output of channel 1 will allow the oscillator to run. the external switch transistor will eventually pumpup the output capacitor until its voltage exceeds the input threshold of channel 1. the output of channel 1 will then switch low and disable the oscillator. the oscillator will commence operation when the output voltage falls below the lower threshold of channel 1.
mc34161 mc33161 14 motorola analog ic device data outline dimensions p suffix plastic package case 62605 issue k d suffix plastic package case 75106 (so8) issue t notes: 1. dimension l to center of lead when formed parallel. 2. package contour optional (round or square corners). 3. dimensioning and tolerancing per ansi y14.5m, 1982. 14 5 8 f note 2 a b t seating plane h j g d k n c l m m a m 0.13 (0.005) b m t dim min max min max inches millimeters a 9.40 10.16 0.370 0.400 b 6.10 6.60 0.240 0.260 c 3.94 4.45 0.155 0.175 d 0.38 0.51 0.015 0.020 f 1.02 1.78 0.040 0.070 g 2.54 bsc 0.100 bsc h 0.76 1.27 0.030 0.050 j 0.20 0.30 0.008 0.012 k 2.92 3.43 0.115 0.135 l 7.62 bsc 0.300 bsc m 10 10 n 0.76 1.01 0.030 0.040 �� seating plane 1 4 5 8 a 0.25 m cb ss 0.25 m b m h � c x 45 � l dim min max millimeters a 1.35 1.75 a1 0.10 0.25 b 0.35 0.49 c 0.19 0.25 d 4.80 5.00 e 1.27 bsc e 3.80 4.00 h 5.80 6.20 h 0 7 l 0.40 1.25 � 0.25 0.50 � � notes: 1. dimensioning and tolerancing per asme y14.5m, 1994. 2. dimensions are in millimeter. 3. dimension d and e do not include mold protrusion. 4. maximum mold protrusion 0.15 per side. 5. dimension b does not include dambar protrusion. allowable dambar protrusion shall be 0.127 total in excess of the b dimension at maximum material condition. d e h a b e b a1 c a 0.10
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mc34161 mc33161 16 motorola analog ic device data mfax is a trademark of motorola, inc. how to reach us: usa / europe / locations not listed : motorola literature distribution; japan : nippon motorola ltd.: spd, strategic planning office, 141, p.o. box 5405, denver, colorado 80217. 13036752140 or 18004412447 4321 nishigotanda, shagawaku, tokyo, japan. 0354878488 customer focus center: 18005216274 mfax ? : rmfax0@email.sps.mot.com touchtone 1 6022446609 asia / pacific : motorola semiconductors h.k. ltd.; 8b tai ping industrial park, motorola fax back system us & canada only 18007741848 51 ting kok road, tai po, n.t., hong kong. 85226629298 http://sps.motorola.com/mfax/ home page : http://motorola.com/sps/ mc34161/d ?
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