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MIC5011 Micrel, Inc. MIC5011 Minimum Parts High- or Low-Side MOSFET Driver General Description The MIC5011 is the "minimum parts count" member of the Micrel MIC501X driver family. These ICs are designed to drive the gate of an N-channel power MOSFET above the supply rail in high-side power switch applications. The 8-pin MIC5011 is extremely easy to use, requiring only a power FET and nominal supply decoupling to implement either a high- or low-side switch. The MIC5011 charges a 1nF load in 60s typical with no external components. Faster switching is achieved by adding two 1nF charge pump capacitors. Operation down to 4.75V allows the MIC5011 to drive standard MOSFETs in 5V low-side applications by boosting the gate voltage above the logic supply. In addition, multiple paralleled MOSFETs can be driven by a single MIC5011 for ultra-high current applications. Other members of the Micrel driver family include the MIC5013 protected 8-pin driver. For new designs, Micrel recommends the pin-compatible MIC5014 MOSFET driver. Features * 4.75V to 32V operation * Less than 1A standby current in the "off" state * Internal charge pump to drive the gate of an N-channel power FET above supply * Available in small outline SOIC packages * Internal zener clamp for gate protection * Minimum external parts count * Can be used to boost drive to low-side power FETs operating on logic supplies * 25s typical turn-on time with optional external capacitors * Implements high- or low-side drivers Applications * * * * Lamp drivers Relay and solenoid drivers Heater switching Power bus switching Typical Applications 14.4V ON Ordering Information Part Number Standard MIC5011BN Pb-Free MIC5011YN Temperature Range -40C to +85C Package 8-pin Plastic DIP 8-pin SOIC 10F + 1 V+ MIC5011 C1 8 Control Input OFF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 MIC5011BM MIC5011YM -40C to +85C IRF531 #6014 Figure 1. High Side Driver ON 5V 48V 1 V+ Note: The MIC5011 is ESD sensitive. 10F + MIC5011 C1 8 Control Input OFF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 100W Heater IRF530 Protected under one or more of the following Micrel patents: patent #4,951,101; patent #4,914,546 Figure 2. Low Side Driver Micrel, Inc. * 2180 Fortune Drive * San Jose, CA 95131 * USA * tel + 1 (408) 944-0800 * fax + 1 (408) 474-1000 * http://www.micrel.com July 2005 1 MIC5011 MIC5011 Micrel, Inc. (V+), Absolute Maximum Ratings (Note 1, 2) Supply Voltage Pin 1 Input Voltage, Pin 2 Source Voltage, Pin 3 Current into Pin 3 Gate Voltage, Pin 5 Junction Temperature -0.5V to 36V -10V to V+ -10V to V+ 50mA -1V to 50V 150C Operating Ratings (Notes 1, 2) Power Dissipation 1.25W JA (Plastic DIP) 100C/W JA (SOIC) 170C/W Ambient Temperature: B version -40C to +85C Storage Temperature -65C to +150C Lead Temperature 260C (Soldering, 10 seconds) Supply Voltage (V+), Pin 1 4.75V to 32V high side 4.75V to 15V low side Pin Description (Refer to Typical Applications) Pin Number 1 2 3 4 5 6, 7, 8 Pin Name V+ Input Source Ground Gate C2, Com, C1 Drives and clamps the gate of the power FET. Will be clamped to approximately -0.7V by an internal diode when turning off inductive loads. Optional 1nF capacitors reduce gate turn-on time; C2 has dominant effect. Pin Function Supply; must be decoupled to isolate from large transients caused by the power FET drain. 10F is recommended close to pins 1 and 4. Turns on power MOSFET when taken above threshold (3.5V typical). Requires <1 A to switch. Connects to source lead of power FET and is the return for the gate clamp zener. Can safely swing to -10V when turning off inductive loads. Pin Configuration 1 2 3 4 MIC5011 V+ Input Source Gnd C1 8 Com 7 C2 6 5 Gate MIC5011 2 July 2005 MIC5011 Test circuit. TA = -55C to +125C, V+ = 15V, all switches open, unless otherwise specified. Parameter Supply Current, I1 Conditions V+ = 32V VIN = 0V, S2 closed VIN = 5V, S2 closed VIN = V+ = 32V Min Typical 0.1 8 1.6 4.5 5.0 -1 1 5 7 24 11 11 10 27 12.5 13 25 4 15 16 50 10 Max 10 20 4 2 Micrel, Inc. Electrical Characteristics (Note 3) Units A mA mA V V V A A pF V V V V s s V+ = 5V Logic Input Voltage V+ = 4.75V V+ = 15V Logic Input Current, I2 Input Capacitance Gate Drive, VGATE Zener Clamp, Gate Turn-on Time, tON (Note 4) Gate Turn-off Time, tOFF Note 1 Note 2 Note 3 Note 4 Adjust VIN for VGATE low V+ = 32V Adjust VIN for VGATE high VIN = 32V V+ = 4.75V, IGATE = 0, VIN = 4.5V V+ = 15V, VS = 15V = 32V, VS = 32V VIN = 0V Adjust VIN for VGATE high Pin 2 S1, S2 closed, VS = V+, VIN = 5V S2 closed, VIN = 5V V+ V+ = 15V, IGATE = 100A, VIN = 5V VGATE - VSOURCE VIN switched from 5 to 0V; measure time for VGATE to reach 1V VIN switched from 0 to 5V; measure time for VGATE to reach 20V Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Electrical specifications do not apply when operating the device beyond its specified Operating Ratings. The MIC5011 is ESD sensitive. Minimum and maximum Electrical Characteristics are 100% tested at TA = 25C and TA = 85C, and 100% guaranteed over the entire range. Typicals are characterized at 25C and represent the most likely parametric norm. Test conditions reflect worst case high-side driver performance. Low-side and bootstrapped topologies are significantly faster--see Applications Information. Maximum value of switching speed seen at 125C, units operated at room temperature will reflect the typical values shown. Test Circuit V+ + 1F 1 V+ 2 Input MIC5011 C1 8 Com 7 1nF 1nF VGATE V IN 500 1W S2 VS 3 Source C2 6 4 Gnd Gate 5 1nF S1 I5 July 2005 3 MIC5011 MIC5011 Micrel, Inc. Typical Characteristics (Continued) 12 10 8 6 4 2 0 0 5 10 15 20 25 30 35 Supply Current 14 12 10 8 6 4 2 0 0 DC Gate Voltage above Supply 3 6 9 12 15 SUPPLY VOLTAGE (V) SUPPLY VOLTAGE (V) High-side Turn-on Time* 350 140 300 250 200 150 100 50 0 0 3 6 9 12 15 CGATE =1 nF 120 100 80 60 40 20 0 0 High-side Turn-on Time* TURN-ON TIME (S) CGATE =1 nF C2=1 nF 3 6 9 12 15 SUPPLY VOLTAGE (V) SUPPLY VOLTAGE (V) High-side Turn-on Time* 3.5 1.4 3.0 2.5 2.0 1.5 1.0 0.5 0 0 3 6 9 12 15 CGATE =10 nF High-side Turn-on Time* TURN-ON TIME (mS) 1.2 1.0 0.8 0.6 0.4 0.2 0 0 3 6 9 12 15 CGATE =10 nF C2=1 nF TURN-ON TIME (mS) SUPPLY VOLTAGE (V) * Time for gate to reach V+ + 5V in test circuit with VS = V+ - 5V. SUPPLY VOLTAGE (V) 4 July 2005 MIC5011 MIC5011 Micrel, Inc. Typical Characteristics (Continued) 1000 Low-side Turn-on Time for Gate = 5V 1000 Low-side Turn-on Time for Gate = 5V C2=1 nF TURN-ON TIME (S) CGATE =10 nF TURN-ON TIME (S) 300 100 30 10 3 1 0 3 6 300 100 30 10 3 1 0 CGATE =10 nF CGATE =1 nF CGATE =1 nF 9 12 15 3 6 9 12 15 SUPPLY VOLTAGE (V) SUPPLY VOLTAGE (V) 3000 Low-side Turn-on Time for Gate = 10V CGATE =10 nF 3000 Low-side Turn-on Time for Gate = 10V C2=1 nF CGATE =10 nF TURN-ON TIME (S) 300 100 30 10 3 0 3 6 9 12 15 TURN-ON TIME (S) 1000 1000 300 100 30 10 3 0 3 6 9 12 15 CGATE =1 nF CGATE =1 nF SUPPLY VOLTAGE (V) SUPPLY VOLTAGE (V) Turn-off Time NORMALIZED TURN-ON TIME 50 Turn-on Time 2.0 1.75 1.5 TURN-ON TIME (S) 40 30 20 10 0 0 CGATE =10 nF 1.25 1.0 CGATE =1 nF 0.75 0.5 -25 0 25 50 75 100 125 3 6 9 12 15 SUPPLY VOLTAGE (V) DIE TEMPERATURE (C) 5 MIC5011 July 2005 MIC5011 Micrel, Inc. 200 150 100 50 VGATE =V+ CHARGE-PUMP CURRENT (mA) CHARGE-PUMP CURRENT (A) 250 Charge Pump Output Current 1.0 0.8 0.6 0.4 0.2 0 Charge Pump Output Current VGATE =V+ VGATE =V++5V VGATE =V + +5V C2=1 nF VS=V +-5V 0 5 10 15 20 25 30 VS=V +-5V 0 0 5 10 15 20 25 30 SUPPLY VOLTAGE (V) SUPPLY VOLTAGE (V) Block Diagram Ground 4 V+ 1 C1 Com C2 876 MIC5011 5 Gate CHARGE PUMP 500 Input 2 LOGIC 12.5V 3 Source Applications Information Functional Description (Refer to Block Diagram) The MIC5011 functions are controlled via a logic block connected to the input pin 2. When the input is low, all functions are turned off for low standby current and the gate of the power MOSFET is also held low through 500 to an N-channel switch. When the input is taken above the turn-on threshold (3.5V typical), the N-channel switch turns off and the charge pump is turned on to charge the gate of the power FET. MIC5011 6 The charge pump incorporates a 100kHz oscillator and onchip pump capacitors capable of charging 1nF to 5V above supply in 60s typical. With the addition of 1nF capacitors at C1 and C2, the turn-on time is reduced to 25s typical (see Figure 3). The charge pump is capable of pumping the gate up to over twice the supply voltage. For this reason, a zener clamp (12.5V typical) is provided between the gate pin 5 and source pin 3 to prevent exceeding the VGS rating of the MOSFET at high supplies. July 2005 MIC5011 Micrel, Inc. Applications Information (Continued) Construction Hints High current pulse circuits demand equipment and assembly techniques that are more stringent than normal, low current lab practices. The following are the sources of pitfalls most often encountered during prototyping. Supplies: many bench power supplies have poor transient response. Circuits that are being pulse tested, or those that operate by pulse-width modulation will produce strange results when used with a supply that has poor ripple rejection, or a peaked transient response. Always monitor the power supply voltage that appears at the drain of a high-side driver (or the supply side of the load in a low-side driver) with an oscilloscope. It is not uncommon to find bench power supplies in the 1 kW class that overshoot or undershoot by as much as 50% when pulse loaded. Not only will the load current and voltage measurements be affected, but it is possible to over-stress various components--especially electrolytic capacitors--with possibly catastrophic results. A 10F supply bypass capacitor at the chip is recommended. Residual Resistances: Resistances in circuit connections may also cause confusing results. For example, a circuit may employ a 50m power MOSFET for low drop, but careless construction techniques could easily add 50 to 100m resistance. Do not use a socket for the MOSFET. If the MOSFET is a TO-220 type package, make high-current drain connections to the tab. Wiring losses have a profound effect on high-current circuits. A floating millivoltmeter can identify connections that are contributing excess drop under load. Circuit Topologies The MIC5011 is suited for use with standard MOSFETs in high- or low-side driver applications. In addition, the MIC5011 works well in applications where, for faster switching times, the supply is bootstrapped from the MOSFET source output. Low voltage, high-side drivers (such as shown in Figure 1) are the slowest; their speed is reflected in the gate turn-on time specifications. The fastest drivers are the low-side and bootstrapped high-side types (Figures 2 and 4). Load current switching times are often much faster than the time to full gate enhancement, depending on the circuit type, the MOSFET, and the load. Turn-off times are essentially the same for all circuits (less than 10s to VGS = 1V). The choice of one topology over another is based on a combination of considerations including speed, voltage, and desired system characteristics. High-Side Driver (Figure 1). The high-side topology works well down to V+ = 7V with standard MOSFETs. From 4.75 to 7V supply, a logic-level MOSFET can be substituted since the MIC5011 will not reach 10V gate enhancement (10V is the maximum rating for logic-compatible MOSFETs). High-side drivers implemented with MIC501X drivers are self-protected against inductive switching transients. During turn-off an inductive load will force the MOSFET source 5V or more below ground, while the MIC5011 holds the gate at ground potential. The MOSFET is forced into conduction, July 2005 7 and it dissipates the energy stored in the load inductance. The MIC5011 source pin (3) is designed to withstand this negative excursion without damage. External clamp diodes are unnecessary. Low-Side Driver (Figure 2). A key advantage of the lowside topology is that the load supply is limited only by the MOSFET BVDSS rating. Clamping may be required to protect the MOSFET drain terminal from inductive switching transients. The MIC5011 supply should be limited to 15V in low-side topologies, otherwise a large current will be forced through the gate clamp zener. Low-side drivers constructed with the MIC501X family are also fast; the MOSFET gate is driven to near supply immediately when commanded ON. Typical circuits achieve 10V enhancement in 10s or less on a 12 to 15V supply. Modifying Switching Times (Figure 3). High-side switching times can be improved by a factor of 2 or more by adding external charge pump capacitors of 1nF each. In cost-sensitive applications, omit C1 (C2 has a dominant effect on speed). Do not add external capacitors to the MOSFET gate. Add a resistor (1k to 51k) in series with the gate to slow down the switching time. 14.4V ON 10F + 1 V+ MIC5011 C1 8 Control Input OFF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 1nF 1nF IRF531 LOAD Figure 3. High Side Driver with External Charge Pump Capacitors Bootstrapped High-Side Driver (Figure 4). The speed of a high-side driver can be increased to better than 10s by bootstrapping the supply off of the MOSFET source. This topology can be used where the load is pulse-width modulated (100Hz to 20kHz), or where it is energized continuously. The Schottky barrier diode prevents the MIC5011 supply pin from dropping more than 200mV below the drain supply, and it also improves turn-on time on supplies of less than 10V. Since the supply current in the "off" state is only a small leakage, the 100nF bypass capacitor tends to remain charged for several seconds after the MIC5011 is turned off. In a PWM application the chip supply is sustained at a higher potential than the system supply, which improves switching time. MIC5011 MIC5011 Micrel, Inc. Applications Information (Continued) 7 to 15V 1N5817 1N4001 (2) 100nF + 10F 15V Control Input 1 V+ 2 Input MIC5011 C1 8 Com 7 IRF540 33pF 33k 100k 4N35 To MIC5011 Input MPSA05 3 Source C2 6 4 Gnd Gate 5 10mA Control Input 100k 1k LOAD Figure 4. Bootstrapped High-Side Driver Opto-Isolated Interface (Figure 5). Although the MIC5011 has no special input slew rate requirement, the lethargic transitions provided by an opto-isolator may cause oscillations on the rise and fall of the output. The circuit shown accelerates the input transitions from a 4N35 opto-isolator by adding hysteresis. Opto-isolators are used where the control circuitry cannot share a common ground with the MIC5011 and high-current power supply, or where the control circuitry is located remotely. This implementation is intrinsically safe; if the control line is severed the MIC5011 will turn OFF. Industrial Switch (Figure 6). The most common manual control for industrial loads is a push button on/off switch. The "on" button is physically arranged in a recess so that in a panic situation the "off" button, which extends out from the control box, is more easily pressed. This circuit is Figure 5. Improved Opto-Isolator Performance compatible with control boxes such as the CR2943 series (GE). The circuit is configured so that if both switches close simultaneously, the "off" button has precedence. This application also illustrates how two (or more) MOSFETs can be paralleled. This reduces the switch drop, and distributes the switch dissipation into multiple packages. High-Voltage Bootstrap (Figure 7). Although the MIC5011 is limited to operation on 4.75 to 32V supplies, a floating bootstrap arrangement can be used to build a high-side switch that operates on much higher voltages. The MIC5011 and MOSFET are configured as a low-side driver, but the load is connected in series with ground. Power for the MIC5011 is supplied by a charge pump. A 20kHz square wave (15Vp-p) drives the pump capacitor and delivers current to a 100F storage capacitor. A zener 24V 100k + 1 V+ MIC5011 CR2943-NA102A ( GE ) ON C1 8 10F OFF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 IRFP044 (2) 330k LOAD Figure 6. 50-Ampere Industrial Switch MIC5011 8 July 2005 MIC5011 Micrel, Inc. Applications Information (Continued) 15V 33k 1N4003 (2) 100k 4N35 33pF MPSA05 3 Source C2 6 4 Gnd Gate 5 1 V+ 2 Input MIC5011 1N4746 C1 8 Com 7 + 100F 90V 1nF IRFP250 10mA Control Input 100k 1/4 HP, 90V 5BPB56HAA100 ( GE ) M 1k 100nF 200V 1N4003 15Vp-p, 20kHz Squarewave Figure 7. High-Voltage Bootstrapped Driver Cross conduction increases output device power dissipation. Speed is also important, since PWM control requires the outputs to switch in the 2 to 20kHz range. The circuit of Figure 8 utilizes fast configurations for both the top- and bottom-side drivers. Delay networks at each input provide a 2 to 3s dead time effectively eliminating cross conduction. Two of these circuits can be connected together to form an H-bridge for locked antiphase or sign/ magnitude control. 15V 1N5817 1N4001 (2) + 1F diode limits the supply to 18V. When the MIC5011 is off, power is supplied by a diode connected to a 15V supply. The circuit of Figure 5 is put to good use as a barrier between low voltage control circuitry and the 90V motor supply. Half-Bridge Motor Driver (Figure 8). Closed loop control of motor speed requires a half-bridge driver. This topology presents an extra challenge since the two output devices should not cross conduct (shoot-through) when switching. 1N4148 1 V+ MIC5011 100nF C1 8 22k 220pF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 IRF541 PWM INPUT 15V + 10F C1 8 M 10A Stalled 12V, 10k 1 V+ MIC5011 22k 2N3904 1nF 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 IRF541 Figure 8. Half-Bridge Motor Driver July 2005 9 MIC5011 MIC5011 Micrel, Inc. Applications Information (Continued) 12V 12V 100k + 1N4148 1 V+ MIC5011 10F + R 330k 1 V+ MIC5011 10F + C1 8 47F 2 Input 3 Source 4 Gnd C1 8 Com 7 330k 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 C2 6 Gate 5 IRFZ44 IRFZ44 10k 100 OUT P UT (Delay=2.5s) 1N4148 100nF T START RUN STOP M Figure 9. 30-Ampere Time-Delay Relay Time-Delay Relay (Figure 9). The MIC5011 forms the basis of a simple time-delay relay. As shown, the delay commences when power is applied, but the 100k/1N4148 could be independently driven from an external source such as a switch or another high-side driver to give a delay relative to some other event in the system. Hysteresis has been added to guarantee clean switching at turn-on. Motor Driver with Stall Shutdown (Figure 10). Tachometer feedback can be used to shut down a motor driver circuit when a stall condition occurs. The control switch is a 3-way type; the "START" position is momentary and forces the driver ON. When released, the switch returns to the "RUN" position, and the tachometer's output is used to hold the MIC5011 input ON. If the motor slows down, the tach output is reduced, and the MIC5011 switches OFF. Resistor "R" sets the shutdown threshold. Electronic Governor (Figure 11). The output of an ac tachometer can be used to form a PWM loop to maintain the speed of a motor. The tachometer output is rectified, partially filtered, and fed back to the input of the MIC5011. When the motor is stalled there is no tachometer output, and MIC5011 input is pulled high delivering full power to the motor. If the motor spins fast enough, the tachometer output is sufficient to pull the MIC5011 input low, shutting the output off. Since the rectified waveform is only partially filtered, the input oscillates around its threshold causing the MIC5011 to switch on and off at the frequency of the tachometer signal. A PWM action results since the average dc voltage at the input decreases as the motor spins faster. The 1k potentiometer is used to set the running speed of the motor. Loop gain (and speed regulation) is increased by increasing the value of the 100nF filter capacitor. The performance of such a loop is imprecise, but stable and inexpensive. A more elaborate loop would consist of a PWM controller and a half-bridge. 12V Figure 10. Motor Stall Shutdown 15V 330k 330k 1 V+ MIC5011 10F + C1 8 2 Input Com 7 3 Source C2 6 4 Gnd Gate 5 1nF IRF541 1N4148 100nF 15V 1k T M Figure 11. Electronic Governor MIC5011 10 July 2005 MIC5011 Micrel, Inc. ON. C1 is discharged, and C2 is charged to supply through Q5. For the second phase Q4 turns off and Q3 turns on, pushing pin C2 above supply (charge is dumped into the gate). Q3 also charges C1. On the third phase Q2 turns off and Q1 turns on, pushing the common point of the two capacitors above supply. Some of the charge in C1 makes its way to the gate. The sequence is repeated by turning Q2 and Q4 back on, and Q1 and Q3 off. In a low-side application operating on a 12 to 15V supply, the MOSFET is fully enhanced by the action of Q5 alone. On supplies of more than approximately 14V, current flows directly from Q5 through the zener diode to ground. To prevent excessive current flow, the MIC5011 supply should be limited to 15V in low-side applications. The action of Q5 makes the MIC5011 operate quickly in low-side applications. In high-side applications Q5 precharges the MOSFET gate to supply, leaving the charge pump to carry the gate up to full enhancement 10V above supply. Bootstrapped high-side drivers are as fast as lowside drivers since the chip supply is boosted well above the drain at turn-on. Applications Information (Continued) Gate Control Circuit When applying the MIC5011, it is helpful to understand the operation of the gate control circuitry (see Figure 12). The gate circuitry can be divided into two sections: 1) charge pump (oscillator, Q1-Q5, and the capacitors) and 2) gate turn-off switch (Q6). When the MIC5011 is in the OFF state, the oscillator is turned off, thereby disabling the charge pump. Q5 is also turned off, and Q6 is turned on. Q6 holds the gate pin (G) at ground potential which effectively turns the external MOSFET off. Q6 is turned off when the MIC5011 is commanded on, and Q5 pulls the gate up to supply (through 2 diodes). Next, the charge pump begins supplying current to the gate. The gate accepts charge until the gate-source voltage reaches 12.5V and is clamped by the zener diode. A 2-output, three-phase clock switches Q1-Q4, providing a quasi-tripling action. During the initial phase Q4 and Q2 are V + Q5 Q3 Q1 125pF 125pF C1 C1 Q2 COM C2 Q4 C2 100 kHz OSCILLATOR OFF ON G 500 Q6 G AT E CLAMP ZENER 12.5V S Figure 12. Gate Control Circuit Detail July 2005 11 MIC5011 MIC5011 Micrel, Inc. Package Information PIN 1 DIMENSIONS: INCH (MM) 0.380 (9.65) 0.370 (9.40) 0.135 (3.43) 0.125 (3.18) 0.255 (6.48) 0.245 (6.22) 0.300 (7.62) 0.013 (0.330) 0.010 (0.254) 0.018 (0.57) 0.100 (2.54) 0.130 (3.30) 0.0375 (0.952) 0.380 (9.65) 0.320 (8.13) 8-Pin Plastic DIP (N) 0.026 (0.65) MAX) PIN 1 0.157 (3.99) 0.150 (3.81) DIMENSIONS: INCHES (MM) 0.050 (1.27) TYP 0.020 (0.51) 0.013 (0.33) 0.0098 (0.249) 0.0040 (0.102) 0-8 SEATING PLANE 45 0.010 (0.25) 0.007 (0.18) 0.064 (1.63) 0.045 (1.14) 0.197 (5.0) 0.189 (4.8) 0.050 (1.27) 0.016 (0.40) 0.244 (6.20) 0.228 (5.79) 8-Pin SOIC (M) MICREL INC. TEL + 1 (408) 944-0800 FAX + 1 (408) 474-1000 WEB http://www.micrel.com 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA This information furnished by Micrel in this data sheet is believed to be accurate and reliable. However no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser's own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. (c) 1998 Micrel, Inc. MIC5011 12 July 2005 |
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