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| TK75050 SMART MOSFET DRIVER FEATURES s 20 ns Rise and Fall Times into 1000 pF s 550 A Standby Current Consumption s Undervoltage Lockout Combined with First Pulse Wake-Up Feature * s Cycle-by-Cycle Current Limiting s Current Sense Voltage Spike Cancellation when Used with Gate Charge Recovery Circuit * s Thermal Overload Protection s TTL/CMOS Compatible Input APPLICATIONS s s s s Driving of Power MOSFETs and IGBTs Switch Mode Power Supplies Step Motor Drivers Solenoid Drivers DESCRIPTION The TK75050 is a non-inverting buffer to drive high power insulated gate transistors (e.g., MOSFETs and IGBTs). The output can source or sink 2 A into a 10,000 pF equivalent load. The IC features built-in cycle-by-cycle current limiting. Its Undervoltage Lockout (UVLO) circuit is combined with a First Pulse Wake-up Feature*. The chip has thermal overload protection. Using the IC in the Gate Charge Recovery* application, the switching spike developed across the current sense resistor practically becomes negligible. Due to its low standby current and first-pulse wake-up feature, the device can be used in selfbiased power supplies. The IC's high-speed cycle-bycycle current limiting capability eliminates the short circuit runaway problem which characterizes most currentcontrolled converters. The IC is well suited to provide supplementary overload protection in voltage-controlled converters, too. The TK75050 is available in the widely used 8-pin DIP package. *Toko proprietary feature: See "Application Information" section. UVLO 11/10 V STARTUP R Q EN BIAS EN INPUT OUTPUT 1.6/1.0 V OVERLOAD R Q S PGND/CS T 155/80 C THERMAL OVERLOAD CURRENT OVERLOAD 1.0/0.9 V S TK75050 PGND/CS INPUT 7505 0 GND GND GND GND OUTPUT VCC BLOCK DIAGRAM VCC ORDERING INFORMATION TK75050D Tape/Reel Code Temperature Code PACKAGE CODE D: DIP-8 GND EXTENDED TEMP. RANGE I: -40 TO +85 C TAPE/REEL CODE TL: Tape Left January 1999 TOKO, Inc. Page 1 TK75050 ABSOLUTE MAXIMUM RATINGS Supply Voltage (Low Impedance Source) ................ 14 V Power Dissipation TK75050D (Note 1) .............. 825 mW Storage Temperature Range ................... -55 to +150 C Operating Temperature Range ...................-20 to +70 C Extended Temperature Range ................... -40 to +85 C Junction Temperature .......................................... 150 C Lead Soldering Temperature (10 s) ..................... 235 C TK75050 ELECTRICAL CHARACTERISTICS Test conditions: VCC = 12 V, TA = Tj = Full Operating Temperature Range, DC Test Setup 1, unless otherwise specified. SYMBOL PARAMETER TEST CONDITIONS MIN TYP MAX UNITS POWER SUPPLY SECTION ICC(STBY) ICC(L) ICC(H) ICC(SD) IPGND/CS Supply Current (Standby), (Note 2) Supply Current (Output LOW) Supply Current (Output HIGH) Suppy Current (Output SHUTDOWN) PGND/CS Current (Output LOW) VIN = 0 V Before Wake-Up VIN = 0 V After Wake-Up VIN = 2.4 V After Wake-up Current or Thermal Overload VIN = 0 V After Wake-up 55 0 17 14 19 4 1000 26 18 24 10 A mA mA mA mA UNDERVOLTAGE LOCKOUT SECTION VCC(ON) VCC(OFF) Suppy Voltage (UVLO HIGH Threshold) Suppy Voltage (UVLO LOW Threshold) VCC Sweeps Upward VCC Sweeps Downward 10.4 9.3 11.0 10.0 11.4 10.4 V V INPUT SECTION VIN(L) VIN(H) IIN(L) IIN(H) VIN(WU) Input Voltage (LOW Threshold) Input Voltage (HIGH Threshold) Input Current (LOW) Input Current (HIGH) Input Voltage (Wake-up Threshold) VIN = 0 V VIN = 2.4 V 0.5 -250 0.6 1.0 1.6 -100 10 1.25 25 2.25 2.1 V V A A V OUTPUT SECTION VOUT(L) Output Voltage (LOW) ISINK = 50 mA ISINK = 1.0 A Output Voltage (HIGH) Maximum Output Sink or Source Current, (Note 3) Standby Output Pull-down Current ISOURCE = 50 mA ISOURCE = 1.0 A CL = 10,000 pF VCC = 9 V VOUT = 8 V VOUT = 2 V 1 0.3 9.7 8.0 0.25 3.0 10.5 9.5 2.0 2.5 0.7 0.5 3.8 V V V V A mA mA VOUT(H) IOUT(MAX) IOUT(STBY) Page 2 January 1999 TOKO, Inc. TK75050 TK75050 ELECTRICAL CHARACTERISTICS (CONT.) Test conditions: VCC = 12 V, TA = Tj = Full Operating Temperature Range, DC Test Setup 1, unless otherwise specified. SYMBOL PARAMETER TEST CONDITIONS MIN TYP MAX UNITS THERMAL OVERLOAD PROTECTION SECTION Tj(OFF) Junction Temperature, Thermal Overload Shutdown Threshold, (Note 3) Temperature Sweeps Upward in Normal Mode 150 C Tj(ON) Junction Temperature, Turn Back to Temperature Sweeps Downward Normal Mode Threshold, (Note 3) in Thermal Shutdown Mode 80 C CURRENT OVERLOAD PROTECTION SECTION VCL VCL(HYST) Current Sense Voltage, Current Limit Threshold Current Sense Voltage, Current Limit Hysteresis, (Note 3) VCS Sweeps Upward, TA = 25 C, DC Test Setup 2 DC Test Setup 2 0.8 0.95 100 1.1 V mV SWITCHING CHARACTERISTICS tDR tR tDF tF tD(COS) Delay Time (RISE) Rise Time Delay Time (FALL) Fall Time Delay Time, Current Overload Shutdown, (Note 3) CL = 1000 pF, AC Test Setup 3 CL = 1000 pF, AC Test Setup 3 CL = 1000 pF, AC Test Setup 3 CL = 1000 pF, AC Test Setup 3 CL = 1000 pF, VCS = 200 mV, AC Test Setup 3 20 20 20 20 120 45 40 45 40 ns ns ns ns ns Note 1: Power dissipation is 825 mW when mounted. Derate at 6.6 mW/C for operation above 25C. Note 2: Conditions for "wake-up": either 1) VIN exceeds VIN(H), stays above VIN(L), and VCC passes VCC(ON) or 2) VCC exceeds VCC(ON), stays above VCC(OFF), and VIN exceeds VIN(H). Conditions for "standby": either 1) VCC never exceeds VCC(ON) or 2) VCC drops below VCC(OFF) or 3) VIN never exceeds VIN(H). Note 3: Guaranteed by design; not 100% tested. January 1999 TOKO, Inc. Page 3 TK75050 TEST CIRCUITS DC TEST SETUP 1 DC TEST SETUP 2 + 100 nF 10 F + ISINK 10000 F VCC IN OUT SW2 + VCC 100 nF 10 F VCC IN + + VCC + VIN GND PGND/CS SW1 VIN ISOURCE + GND 10 PGND/CS + VCS - Note: SW1 and SW2 are open by default. To avoid excessive dissipation, they are exclusively closed only for less than 100 ms to measure the appropriate output voltages VOUT(H) and VOUT(L) at specified currents ISOURCE and ISINK, respectively. AC TEST SETUP 3 + 100 nF 10 F VCC IN SYNCH VIN PULSE GENERATOR GND Ch A TRIG Ch B OUT PGND/CS + VCC ZOOM IN +TRIG -TRIG 1.6 V CL 1000 pF ZOOM IN 90 % 10 % tDR tDF 1.0 V t 90 % 10 % t tR tF OSCILLOSCOPE AC TEST SETUP 4 + 100 nF 10 F VCC VIN (t) f = 10 kHz D = 1:1 Level = TTL TRIG IN GND IN OUT PGND/CS + VCC - VOUT (t) CL 1000 pF Ch A TRIG IN VIN (t) tD = 10 s T = 100 s +TRIG Ch B t ZOOM IN VCL = 1 V VCS = 50 mV 200 mV VCS ADJ +TRIG t OSCILLOSCOPE Ch C VOUT (t) t t VOUT(L) tD(COS) VCS (t) tW = 10 s ZOOM IN VOUT(H) t 90 % PULSE GENERATOR1 VCS (t) 10 SYNCH OUT f = 10 kHz D = 1:10 Level = ADJ. PULSE GENERATOR2 RS 50 Page 4 January 1999 TOKO, Inc. TK75050 TYPICAL PERFORMANCE CHARACTERISTICS SUPPLY CURRENT VS. TEMPERATURE 20 VCC = 12 V NO LOAD CONNECTED STANDBY CURRENT VS. TEMPERATURE 700 NO LOAD CONNECTED AVERAGE SUPPLY CURRENT VS. FREQUENCY 20 VCC = 12 V NO LOAD CONNECTED 18 ICC (mA) 16 ICC(H) 600 ICC(STBY) (A) VCC = 12 V 18 ICC(AVG) (mA) 16 14 12 VCC = 5 V TA = 25 C ICC(L) 500 VCC = 10 V 14 12 10 -25 25 TA (C) SUPPLY CURRENT VS. SUPPLY VOLTAGE 20 TA = 25 C NO LOAD CONNECTED 400 300 200 TA = 125 C 75 125 -25 25 TA (C) 75 125 10 0.01 0.1 1 10 100 1000 FREQUENCY (kHz) UVLO THRESHOLD VS. TEMPERATURE 11.5 UVLO THRESHOLD (V) VCC(ON) INPUT THRESHOLD VS. TEMPERATURE 2.0 VCC = 12 V 15 ACTIVE MODE 11.0 INPUT THRESHOLD (V) ICC (mA) 1.6 VIN(H) 10 10.5 VCC(OFF) 1.2 VIN(L) 5 SLEEP MODE 10.0 0 2 6 VCC (V) OUTPUT VOLTAGE VS. TEMPERATURE 10.8 VCC = 12 V NO LOAD CONNECTED 9.5 10 14 -25 25 TA (C) CURRENT LIMIT THRESHOLD VS. TEMPERATURE 1.2 VCC = 12 V VIN = VIN(H) VOUT(H) 0.8 75 125 -25 25 TA (C) 75 125 RISE AND FALL TIME VS. TEMPERATURE 28 VCC = 12 V CL = 1000 pF 10.6 10.4 VCL (V) 10.2 1.0 TIME (ns) VOUT (V) 24 tF 0.8 VOUT(L) 20 tR 0.2 0.0 -25 25 TA (C) 75 125 0.6 -25 25 TA (C) 75 125 15 -25 25 TA (C) 75 125 January 1999 TOKO, Inc. Page 5 TK75050 TYPICAL PERFORMANCE CHARACTERISTICS (CONT.) PROPOGATION DELAY VS. TEMPERATURE 36 PROPOGATION DELAY (ns) CURRENT OVERLOAD SHUTDOWN DELAY VS. TEMPERATURE 250 PROPOGATION DELAY (ns) VCC = 12 V CL = 1000 pF VCC = 12 V CL = 1000 pF 32 28 24 tDR 200 VCS = 50 mV tDF 150 100 VCS = 100 mV VCS = 200 mV 20 16 -25 25 TA (C) 75 125 50 0 -25 25 TA (C) 75 125 Page 6 January 1999 TOKO, Inc. TK75050 PIN DESCRIPTION SUPPLY VOLTAGE PIN (VCC) This pin is connected to the supply voltage. Regardless of the state of the other pins, the IC is always in a low-current standby mode when the supply voltage is below the lower threshold of the undervoltage lockout circuit. The IC enters normal mode when two conditions are met simultaneously: 1) the supply voltage exceeds the upper threshold of the undervoltage lockout circuit, and 2) a "first" pulse arrives at the input. That first pulse "wakes up" the IC ( i.e., it enables the highspeed internal circuitry). The First Pulse Wake-Up is a proprietary feature of theTK75050. The feature is proprietary, but use is granted for use with the IC. That feature is indispensable in off-line self-biased powersupply applications where the start-up current is provided by a large-value resistor connected between the rectified line and the IC (see Figure 1). Without the First Pulse Wake-up, the starting current would be equal to the normal supply current, which is prohibitively large for a self-biased start. GROUND PIN (GND) This pin provides ground return connection for the smallsignal portion of the IC. The return of the output stage is not connected here, but to the floating power GND pin. OUTPUT PIN This pin drives the external MOSFET using a totem pole output stage. The peak drive source or sink current is typically 2 A into a 10,000 pF equivalent load. The UVLO circuity ensures that the high-level output voltage will never be less than about 7 V. In standby mode, the output stage is equivalent to a pull-down resistor of about 3 k value, eliminating the need for an external gate to source resistor. Normally, there is no need to add a Schottky diode between the output and ground. In applications, however, with heavy capacitive load located far from the IC or when the IC drives a transformer, the Schottky diode may become necessary. INPUT PIN The input pin receives the signal to be buffered. The incoming signal is processed by a comparator with a 600 mV hysteresis centered around a threshold of about 1.3 V. The hysteresis ensures that noise riding on the input signal does not cause spurious response at the output. POWER GROUND/CURRENT SENSE PIN (PGND/CS) This pin has two distinct functions: 1) it provides a separate, fully floating return path for the turnoff drive current of the output stage and, thus, reduces the internal noise of the IC; 2) by connecting the pin to a current-sense resistor, the IC acts as a fast cycle-by-cycle current limiter. When the voltage between the power-ground pin (PGND/ CS) and the signal-ground pin (GND) exceeds the 0.95 V current-limit threshold, the drive signal is terminated for the remainder of the time while the input signal is high. Once the input signal returned to zero, the latch that stored the information about the presence of the overcurrent is reset, and the IC is ready to acquire another overcurrent event in the next cycle. January 1999 TOKO, Inc. Page 7 TK75050 APPLICATION INFORMATION START-UP Figure 1 shows the application of the TK75050 smart MOSFET driver in a self-biased power supply. VIN granted for use with the TK75050. For a detailed description and application information of the Gate Charge Recovery technique, see the Toko application note "Application Considerations for a Smart Five-Pin MOSFET/IGBT Driver with High-Speed Current-Limit Capability." + VAUX RF IN VCC TK75050 + IN VCC CF OUT OUT 0.95 V PWM CONTROLLER GND PGND/CS VCS (t) + VCS(t) RCS CF IS CONNECTED TO GND 0.95 V VCS(t) CF IS CONNECTED TO PGND/CS FIGURE 1: TK75050 IN A SELF-BIASED POWER SUPPLY Figure 2 shows the typical waveforms during start-up. (a) (b) FIGURE 3: CYCLE-BY-CYCLE CURRENT LIMIT WITH THE TK75050 (a) SCHEMATIC (b) WAVEFORMS MAIN OVERLOAD PROTECTION IN VOLTAGEMODE-CONTROLLED CONVERTERS Figure 4 shows the TK75050 in a voltage-mode-controlled flyback converter. In this application example, the IC provides the main overload protection. PWM ENABLE BOOTSTRAP REGULATION BEGINS UVLO UPPER THRESHOLD UVLO LOWER THRESHOLD VCC (t) VUVLO (t) VIN (t) UVLO CONDITION FIRST PULSE CONDITION DRIVER "WAKES UP" VIN + VIN (t) & VOUT (t) +12 V FIGURE 2: WAVEFORMS DURING START-UP FEEDBACK CYCLE-BY-CYCLE CURRENT LIMIT Figure 3(a) shows how to use the TK75050 as a highspeed cycle-by-cycle current limiter. Figure 3(b) shows the waveforms. Note that the preferred connection for the bottom terminal of the filter capacitor CF is to the PGND/CS pin and not to the GND pin. By connecting CF to the PGND/ CS pin, the capacitive feedthrough of the drive signal that would appear as a leading-edge spike in the current-sense waveform is completely eliminated. This technique, called "Gate Charge Recovery" is patented by Toko, Inc., but is Page 8 VOLTAGE-MODE PWM CONTROLLER FIGURE 4: TK75050 IN A VOLTAGE-MODECONTROLLED CONVERTER January 1999 TOKO, Inc. TK75050 APPLICATION INFORMATION (CONT.) ADDITIONAL OVERLOAD PROTECTION IN PEAKCURRENT-CONTROLLED CONVERTERS Figure 5 shows the TK75050 in a current-mode-controlled forward converter, with optically isolated feedback. In this application the TK75050 helps to achieve a tightly controlled current-limit-characteristic. A tight current limit cannot usually be achieved with only current-mode control due to the presence of the stabilizing ramp. The lack of the stabilizing ensures that the knee current (i.e., the output current where the limiting begins) is only slightly lower than the short-circuit current. The difference between the knee current and the short-circuit current is about one-half of the ripple current in the filter inductor. If a stabilizing ramp were added to the current-sense signal, the difference would be significantly higher. VIN VIN +12 V TK75050 + + + FEEDBACK FIGURE 6: TK75050 IN A CONVERTER WITH AVERAGE CURRENT CONTROL FLOATING DRIVE WITH OVERLOAD PROTECTION + +12 V OC TK75050 CURRENT-MODE PWM CONTROLLER The TK75050 can be used as a driver and current limiter for a floating power switch. Figure 7 shows the IC in a buck converter with transformer-isolated drive. VIN FIGURE 5: TK75050 IN A PEAK-CURRENTCONTROLLED CONVERTER ADDITIONAL OVERLOAD PROTECTION IN AVERAGECURRENT-CONTROLLED CONVERTERS In converters with average current control the peak current information is lost and the response of the current-control loop slows down. The speed of the current-control loop may not be sufficient to provide effective protection against sudden overload or saturation of an inductor or transformer. Figure 6 shows an average-current-controlled boost converter where the TK75050 provides additional fast overload protection. + TK75050 FIGURE 7: TK75050 AS A FLOATING DRIVER IN A BUCK CONVERTER DEMO BOARD The purpose of the board is to demonstrate the high-speed current-limit capability of Toko's TK75050 smart MOSFET driver. In the board a 2-A/500 V MOSFET switch is turned on directly (i.e., without any series impedance) into a DCbus with up to 400 V, at a frequency of 30 kHz. By removing the short across a 3.3 H inductor in series with the MOSFET, it is also possible to investigate the effect of the wiring inductance between the switch and the load. In Page 9 January 1999 TOKO, Inc. TK75050 APPLICATION INFORMATION (CONT.) addition to the short-circuit protection, the board also illustrates how to use the IC for driving and protecting a floating switch. CIRCUIT SCHEMATIC Figure 8 shows the circuit schematic. The operation is as follows: U1, a 5-pin PWM IC (TK75001) generates a 30 kHz square-wave signal, with about 15 V peak-to-peak magnitude and 44% duty ratio. That square-wave signal is connected to the primary winding of a pulse transformer T1 through a coupling capacitor C9 and a small series resistor R11. A voltagedoubler comprising C3, C4, D3 and D4 rectifies the transformed square wave appearing across the secondary winding of the transformer, generating a floating supply voltage of about 12 V for the MOSFET driver IC U2 (TK75050). A drive signal is derived for U2 from the voltage across the diode D4 with the help of the resistive divider R3 and R2. The output of U2 (pin 3) is connected to the gate of the MOSFET Q1 through a 150 ohm resistor R4 and a parallel diode D5. The current of the MOSFET switch is sensed by resistor R5. D6 and D7 protect the PGND/CS pin (pin 1) of U2 from excessive voltage; D8 and D9 prevent the voltages of pins 3 and 1 from swinging below ground by more than 0.3 V. The MOSFET Q1 is connected to a DC-bus through a small inductor L1. That inductor represents the inductance of a wire connection to a load, which is at a distance of approximately 1 meter from the MOSFET. By placing a short across jumper JP1, we can emulate the case when the free-wheeling diode in a buck or boost converter fails. If the inductor L1 is not shorted, a clamp comprising D10, C6 and R7 limits the drain voltage excursion of Q1 to about 60 V above the bus voltage. A test loop is provided for clamp-on type current probes to monitor the current in the MOSFET Q1. Test points TP1 through TP4 are available for measuring the dc bus voltage and the voltage across Q1. The DC-bus is generated by rectifying the line voltage with a bridge rectifier (in the case of 230 VRMS line) or with a voltage doubler (in the case of 115 VRMS line, when jumper JP2 is shorted). Alternatively, a DC source of not more than 400 V can be connected to the line terminals. Notes: (1) Leave JP2 open if you connect more than 250 V dc voltage to the line terminals, otherwise the excess voltage across C7 or C8 can lead to failure of the capacitor. (2) Never operate the circuit from 230 VRMS line with the jumper JP2 shorted. In such a case excess bus voltage will develop that will destroy capacitor C7 and C8 and transistor Q1. TEST LOOP FOR CURRENT PROBE F1 1A SLOW TP4 TEST POINT FOR VOLTAGE OBSERVATION +15 V TP5 D5 Q1 R10 1k D11 1N5226B (3.3 V) D2 C2 1.5 n FB GND VCC + C1 CT GND DRV U1 TK75001 D1 n1 T1 n2 D4 D7 Q1: IRF820 (IR PREFERRED) R3 HS1: HS121-ND (DIGI-KEY, AAVID) 10 k D1, D2, D5, D8, D9: 1N5817 22 k D3, D4, D6, D7: 1N4148 D10: BYV26C D12-15: 1N4005 C1, C4: 10 , 25 V C6: 15 n, 630 V(e.g. ECQ-E6153KF, PANASONIC) C7, C8: 2.2 , 250 V (PANASONIC SU SERIES, RADIAL, ECE-A2EU2R2) L1: 3.3. , 4 A (e.g. R622LY-3R3M, TOKO) T1: RM5/i, 3E1 (PHILIPS), n1 = 40, n2 = 46, SINGLE LAYER WINDINGS, WIRE SIZE TO FILL THE BOBBIN MYLAR INSULATION BETWEEN LAYERS, FOR 1 kV BETWEEN PRIMARY AND SECONDARY JP2: OPEN AT 230 V, SHORTED AT 115 V. R2 D6 C3 1 U2 TK75050 VCC 10 C5 + 0.1 C4 GND IN GND PGND/CS D9 R6 10 OUT R4 150 C9 1 R11 10 D3 D8 D12 JP1 D15 L1 115 OR 230 Vrms C7 R9 1M JP2 C8 R8 1M D14 D13 HS1 D10 R7 R1 R5 0.47 1W C6 1k 1W TP3 TP1 TP2 TEST POINT FOR SCOPE GND CLIP TEST POINTS FOR VCC MEASUREMENT (MAX. 400 VDC) FIGURE 8: CIRCUIT SCHEMATIC Page 10 January 1999 TOKO, Inc. TK75050 APPLICATION INFORMATION (CONT.) Figures 9 and 10 show the measured voltages across Q1 (top trace) and the currents in Q1 (bottom trace). Figure 9 shows the wave forms when there is no inductor in series with Q1 (i.e., L1 is shorted). Figure 10 shows the waveforms when there is an inductor in series with Q1 (i.e., L1 is not shorted). The vertical scales are 100 V/div. (top trace) and 1 A/div (bottom trace). The horizontal scales are 25 ns/div. As can be seen, the peak currents stay below 2.5 A (Figure 9) or 2.8 A (Figure 10). Those numbers correspond to 25% or 40% overshoots above the nominal current-limit threshold of 2 A. Both figures show that the IC shuts off the MOSFET completely in less than 50 ns after the current passed the 2 A threshold. The measured average DC current consumption at a bus voltage of 400 V and a switching frequency of 30 kHz is 4.3 mA when L1 is shorted (Figure 9) and 5.3 mA when L1 is not shorted (Figure 10). SAFETY CONSIDERATIONS/LIABILITY DISCLAIMER Dangerous voltages are present in the demo board. Extreme caution must be used when using and testing the circuit. Only trained personnel, experienced in working with high voltages and power, should operate it. Use an isolating transformer between the line and the circuit if any grounded instrument (including the 20 V auxiliary supply for the square-wave generator at the primary side of transformer T1) is to be connected to the board. Note: Although the two windings of transformer T1 are isolated from each other, the transformer is not designed to provide safety isolation between those windings. Toko, Inc. disclaims any and all liability arising from use or misuse of the demo board described herein. 400V 0V 2A 0A 25ns/div. FIGURE 9 400V 0V 2A 0A 25ns/div. FIGURE 10 January 1999 TOKO, Inc. Page 11 TK75050 PACKAGE OUTLINE Marking Information 8 5 Marking DIP-8 TK75050 Lot Number Marking 75050 6.4 Country of Origin 1 4 9.5 3.3 0.5 min 3.3 + 0.3 3.8 + 0.3 0.25 e + 0.15 - 0.05 + 0.15 - 0.05 e1 7.62 0~ 15 2.54 0.46 0.25 M Dimensions are shown in millimeters Tolerance: x.x = 0.2 mm (unless otherwise specified) Toko America, Inc. Headquarters 1250 Feehanville Drive, Mount Prospect, Illinois 60056 Tel: (847) 297-0070 Fax: (847) 699-7864 TOKO AMERICA REGIONAL OFFICES Midwest Regional Office Toko America, Inc. 1250 Feehanville Drive Mount Prospect, IL 60056 Tel: (847) 297-0070 Fax: (847) 699-7864 Western Regional Office Toko America, Inc. 2480 North First Street , Suite 260 San Jose, CA 95131 Tel: (408) 432-8281 Fax: (408) 943-9790 Eastern Regional Office Toko America, Inc. 107 Mill Plain Road Danbury, CT 06811 Tel: (203) 748-6871 Fax: (203) 797-1223 Semiconductor Technical Support Toko Design Center 4755 Forge Road Colorado Springs, CO 80907 Tel: (719) 528-2200 Fax: (719) 528-2375 Visit our Internet site at http://www.tokoam.com The information furnished by TOKO, Inc. is believed to be accurate and reliable. However, TOKO reserves the right to make changes or improvements in the design, specification or manufacture of its products without further notice. TOKO does not assume any liability arising from the application or use of any product or circuit described herein, nor for any infringements of patents or other rights of third parties which may result from the use of its products. No license is granted by implication or otherwise under any patent or patent rights of TOKO, Inc. Page 12 (c) 1999 Toko, Inc. All Rights Reserved IC-164-TK75050 0798O0.0K January 1999 TOKO, Inc. Printed in the USA |
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