EVALUATION KIT AVAILABLE TC7662B CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER FEATURES GENERAL DESCRIPTION ■ ■ ■ ■ The TC7662B is a pin-compatible upgrade to the Industry standard TC7660 charge pump voltage converter. It converts a +1.5V to +15V input to a corresponding – 1.5 to – 15V output using only two low-cost capacitors, eliminating inductors and their associated cost, size and EMI. The on-board oscillator operates at a nominal frequency of 10kHz. Frequency is increased to 35kHz when pin 1 is connected to V+, allowing the use of smaller external capacitors. Operation below 10kHz (for lower supply current applications) is also possible by connecting an external capacitor from OSC to ground (with pin 1 open). The TC7662B is available in both 8-pin DIP and 8-pin small outline (SO) packages in commercial and extended temperature ranges. ■ Wide Operating Voltage Range: 1.5V to 15V Boost Pin (Pin 1) for Higher Switching Frequency High Power Efficiency is 96% Easy to Use – Requires Only 2 External Non-Critical Passive Components Improved Direct Replacement for Industry Standard ICL7660 and Other Second Source Devices APPLICATIONS ■ ■ ■ ■ ■ Simple Conversion of +5V to ±5V Supplies Voltage Multiplication VOUT = ±nVIN Negative Supplies for Data Acquisition Systems and Instrumentation RS232 Power Supplies Supply Splitter, VOUT = ±VS/2 PIN CONFIGURATION (DIP AND SOIC) 8 V+ BOOST 1 CAP + 2 8 V+ BOOST 1 CAP + 2 7 OSC GND 3 TC7662BCPA 6 LOW VOLTAGE (LV) TC7662BEPA 5 VOUT CAP – 4 GND 3 CAP – 4 7 OSC TC7662BCOA 6 LOW VOLTAGE (LV) TC7662BEOA 5 VOUT ORDERING INFORMATION Temperature Range Part No. Package TC7662BCOA 8-Pin SOIC TC7662BCPA 8-Pin Plastic DIP TC7662BEOA 8-Pin SOIC – 40°C to +85°C TC7662BEPA 8-Pin Plastic DIP – 40°C to +85°C TC7660EV Evaluation Kit for Charge Pump Family 0°C to +70°C 0°C to +70°C FUNCTIONAL BLOCK DIAGRAM V + CAP + 8 BOOST OSC LV 2 1 7 RC OSCILLATOR ÷2 VOLTAGE– LEVEL TRANSLATOR 4 CAP – 6 5 VOUT INTERNAL VOLTAGE REGULATOR LOGIC NETWORK TC7662B 3 GND © 2001 Microchip Technology Inc. DS21469A TC7662B-8 9/11/96 CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B Operating Temperature Range C Suffix .................................................. 0°C to +70°C E Suffix ............................................. – 40°C to +85°C Storage Temperature Range ................ – 65°C to +150°C Lead Temperature (Soldering, 10 sec) ................. +300°C ABSOLUTE MAXIMUM RATINGS* Supply Voltage ...................................................... +16.5V LV, Boost and OSC Inputs Voltage (Note 1) V+<5.5V ..................................... – 0.3V to (V+ + 0.3V) >5.5V .................................. (V+ – 5.5V) to (V+ + 0.3V) Current Into LV (Note 1) V+ >3.5V ............................................................ 20µA Output Short Duration (VSUPPLY ≤ 5.5V) ....................................... Continuous Power Dissipation (TA ≤ 70°C) (Note 2) Plastic DIP ...................................................... 730mW SO ..................................................................470mW * Static-sensitive device. Unused devices must be stored in conductive material. Protect devices from static discharge and static fields. Stresses above 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 above those indicated in the operation sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS: V+ = 5V, TA = +25°C, OSC = Free running, Test Circuit Figure 2, Unless Otherwise Specified. Symbol Parameter Test Conditions I+ Supply Current (Note 3) (Boost pin OPEN OR GND) I+ Supply Current (Boost pin = V+) V+H Supply Voltage Range, High (Note 4) Supply Voltage Range, Low Output Source Resistance RL = ∞, +25°C 0°C ≤ TA ≤ +70°C – 40°C ≤ TA ≤ +85°C – 55°C ≤TA ≤ +125°C 0°C ≤ TA ≤ +70°C – 40°C ≤ TA ≤ +85°C – 55°C ≤ TA ≤ +125°C RL = 10 kΩ, LV Open, TMIN ≤ TA ≤ TMAX + VL ROUT fOSC Oscillator Frequency PEff Power Efficiency VOUTEff ZOSC Voltage Conversion Efficiency Oscillator Impedance RL = 10 kΩ, LV to GND, TMIN ≤ TA ≤ TMAX IOUT = 20mA, 0°C ≤ TA ≤ +70°C IOUT = 20mA, – 40°C ≤ TA ≤ +85°C IOUT = 20mA, – 55°C ≤ TA ≤ +125°C IOUT = 3mA, V+ = 2V, LV to GND , 0°C ≤ TA ≤ +70°C IOUT = 3mA, V+ = 2V, LV to GND , – 40°C ≤ TA ≤ +85°C IOUT = 3mA, V+ = 2V, LV to GND , – 55°C ≤ TA ≤ +125°C COSC = 0,Pin 1 Open or GND Pin 1 = V+ RL = 5kΩ TMIN ≤ TA ≤ TMAX RL = ∞ V+ = 2V V+ = 5V Min Typ Max Unit — — — — — 80 — — — — µA µA µA µA µA 3.0 — 160 180 180 200 300 350 400 15 1.5 — — — — — 65 — — — 3.5 100 120 150 250 V Ω Ω Ω Ω — — 300 Ω — — 400 Ω 5 10 35 96 97 99.9 1 100 — kHz — % — — — % MΩ kΩ 96 95 99 — — V NOTES: 1. Connecting any terminal to voltages greater than V+ or less than GND may cause destructive latch-up. It is recommended that no inputs from sources operating from external supplies be applied prior to “power up” of the TC7662B. 2. Derate linearly above 50°C by 5.5 mW/°C. 3. In the test circuit, there is no external capacitor applied to pin 7. However, when the device is plugged into a test socket, there is usually a very small but finite stray capacitance present, of the order of 5pF. 4. The TC7662B can operate without an external diode over the full temperature and voltage range. This device will function in existing designs which incorporate an external diode with no degradation in overall circuit performance. TC7662B-8 9/11/96 2 © 2001 Microchip Technology Inc. DS21469A CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B DETAILED DESCRIPTION THEORETICAL POWER EFFICIENCY CONSIDERATIONS The TC7662B contains all the necessary circuitry to complete a negative voltage converter, with the exception of two external capacitors which may be inexpensive 1µF polarized electrolytic types. The mode of operation of the device may be best understood by considering Figure 2, which shows an idealized negative voltage converter. Capacitor C1 is charged to a voltage V+ for the half cycle when switches S1 and S3 are closed. (Note: Switches S2 and S4 are open during this half cycle.) During the second half cycle of operation, switches S2 and S4 are closed, with S1 and S3 open, thereby shifting capacitor C1 negatively by V+ volts. Charge is then transferred from C1 to C2 such that the voltage on C2 is exactly V+, assuming ideal switches and no load on C2. The TC7662B approaches this ideal situation more closely than existing non-mechanical circuits. In the TC7662B, the four switches of Figure 2 are MOS power switches; S1 is a P-channel device and S2, S3 and S4 are N-channel devices. The main difficulty with this approach is that in integrating the switches, the substrates of S3 and S4 must always remain reverse biased with respect to their sources, but not so much as to degrade their “ON” resistances. In addition, at circuit start up, and under output short circuit conditions (VOUT = V+), the output voltage must be sensed and the substrate bias adjusted accordingly. Failure to accomplish this would result in high power losses and probable device latchup. The problem is eliminated in the TC7662B by a logic network which senses the output voltage (VOUT) together with the level translators, and switches the substrates of S3 and S4 to the correct level to maintain necessary reverse bias. The voltage regulator portion of the TC7662B is an integral part of the anti-latchup circuitry; however, its inherent voltage drop can degrade operation at low voltages. Therefore, to improve low voltage operation, the “LV” pin should be connected to GND, disabling the regulator. For supply voltages greater than 3.5 volts, the LV terminal must be left open to insure latchup proof operation and prevent device damage. V+ C1 + 10 µF In theory, a voltage converter can approach 100% efficiency if certain conditions are met: A. The drive circuitry consumes minimal power. B. The output switches have extremely low ON resistance and virtually no offset. C. The impedances of the pump and reservoir capacitors are negligible at the pump frequency. The TC7662B approaches these conditions for negative voltage conversion if large values of C1 and C2 are used. Energy is lost only in the transfer of charge between capacitors if a change in voltage occurs. The energy lost is defined by: E = 1/2 C1 (V12 – V22) where V1 and V2 are the voltages on C1 during the pump and transfer cycles. If the impedances of C1 and C2 are relatively high at the pump frequency (refer to Figure 2) compared to the value of RL, there will be a substantial difference in voltages V1 and V2. Therefore, it is desirable not only to make C2 as large as possible to eliminate output voltage ripple, but also to employ a correspondingly large value for C1 in order to achieve maximum efficiency of operation. Dos and Don’ts 1. Do not exceed maximum supply voltages. 2. Do not connect the LV terminal to GND for supply voltages greater than 3.5 volts. 3. Do not short circuit the output to V+ supply for voltages above 5.5 volts for extended periods; however, transient conditions including start-up are okay. S1 S2 VIN C1 IS 1 8 2 7 3 TC7662B 6 4 5 IL V+ (+5V) S3 S4 C2 VOUT = – VIN RL VO NOTE: For large values of COSC (>1000 pF), the values of C1 and C2 should be increased to 100 µF. + C2 10 µF Figure 1. TC7662B Test Circuit © 2001 Microchip Technology Inc. DS21469A Figure 2. Idealized Negative Voltage Capacitor 3 TC7662B-8 9/11/96 CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B voltage and temperature (See the Output Source Resistance graphs), typically 23Ω at +25°C and 5V. Careful selection of C1 and C2 will reduce the remaining terms, minimizing the output impedance. High value capacitors will reduce the 1/(fPUMP x C1) component, and low ESR capacitors will lower the ESR term. Increasing the oscillator frequency will reduce the 1/(fPUMP x C1) term, but may have the side effect of a net increase in output impedance when C1 > 10µF and there is not enough time to fully charge the capacitors every cycle. In a typical application when fOSC = 10kHz and C = C1 = C2 = 10µF: 4. When using polarized capacitors in the inverting mode, the + terminal of C1 must be connected to pin 2 of the TC7662B and the – terminal of C2 must be connected to GND. 5. If the voltage supply driving the TC7662B has a large source impedance (25-30 ohms), then a 2.2µF capacitor from pin 8 to ground may be required to limit the rate of rise of the input voltage to less than 2V/µsec. TYPICAL APPLICATIONS Simple Negative Voltage Converter RO ≅ 2 x 23 + The majority of applications will undoubtedly utilize the TC7662B for generation of negative supply voltages. Figure 3 shows typical connections to provide a negative supply where a positive supply of +1.5V to +15V is available. Keep in mind that pin 6 (LV) is tied to the supply negative (GND) for supply voltages below 3.5 volts. 1 Since the ESRs of the capacitors are reflected in the output impedance multiplied by a factor of 5, a high value could potentially swamp out a low 1/(fPUMP x C1) term, rendering an increase in switching frequency or filter capacitance ineffective. Typical electrolytic capacitors may have ESRs as high as 10Ω. 8 2 3 Output Ripple 7 TC7662B 6 ESR also affects the ripple voltage seen at the output. The total ripple is determined by 2 voltages, A and B, as shown in Figure 4. Segment A is the voltage drop across the ESR of C2 at the instant it goes from being charged by C1 (current flowing into C2) to being discharged through the load (current flowing out of C2). The magnitude of this current change is 2 x IOUT, hence the total drop is 2 x IOUT x ESRC2 volts. Segment B is the voltage change across C2 during time t2, the half of the cycle when C2 supplies current to the load. The drop at B is IOUT x t2/C2 volts. The peak-topeak ripple voltage is the sum of these voltage drops: RO 5 4 – 10 µF + VOUT = –V+ VOUT – V+ + a. b. Figure 3. Simple Negative Converter and its Output Equivalent The output characteristics of the circuit in Figure 3 can be approximated by an ideal voltage source in series with a resistance as shown in Figure 3b. The voltage source has a value of–(V+). The output impedance (RO) is a function of the ON resistance of the internal MOS switches (shown in Figure 2), the switching frequency, the value of C1 and C2, and the ESR (equivalent series resistance) of C1 and C2. A good first order approximation for RO is: VRIPPLE ≅ ( ) 1 2 x fPUMP x C2 + ESRC2 x IOUT RO ≅ 2(RSW1 + RSW3 + ESRC1) + 2(RSW2 + RSW4 + ESRC1) + (fPUMP = fOSC 2 1 fPUMP x C1 t2 RO ≅ 2 x RSW + t1 + ESRC2 0 B , RSWX = MOSFET switch resistance) V Combining the four RSWX terms as RSW, we see that: 1 fPUMP x C1 A + 4 x ESRC1 + ESRC2Ω – (V+) RSW, the total switch resistance, is a function of supply TC7662B-8 9/11/96 + 4 x ESRC1 + ESRC2 RO ≅ (46 + 20 + 5 x ESRC) Ω V+ 10 µF + – 1 (5 x 103 x 10 x 10-6) Figure 4. Output Ripple 4 © 2001 Microchip Technology Inc. DS21469A CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B Paralleling Devices Changing the TC7662B Oscillator Frequency Any number of TC7662B voltage converters may be paralleled to reduce output resistance (Figure 5). The reservoir capacitor, C2, serves all devices, while each device requires its own pump capacitor, C1. The resultant output resistance would be approximately: It may be desirable in some applications (due to noise or other considerations) to increase the oscillator frequency. This is achieved by one of several methods described below: By connecting the BOOSTPin (Pin 1) to V+, the oscillator charge and discharge current is increased and, hence the oscillator frequency is increased by approximately 3-1/2 times. The result is a decrease in the output impedance and ripple. This is of major importance for surface mount applications where capacitor size and cost are critical. Smaller capacitors, e.g., 0.1µF, can be used in conjunction with the Boost Pin in order to achieve similar output currents compared to the device free running with C1 = C2 = 1µF or 10µF. (Refer to graph of Output Source Resistance as a Function of Oscillator Frequency). Increasing the oscillator frequency can also be achieved by overdriving the oscillator from an external clock as shown in Figure 7. In order to prevent device latchup, a 1kΩ resistor must be used in series with the clock output. In a situation where the designer has generated the external clock frequency using TTL logic, the addition of a 10kΩ pullup resistor to V+ supply is required. Note that the pump frequency with external clocking, as with internal clocking, will be 1/2 of the clock frequency. Output transitions occur on the positive-going edge of the clock. ROUT = ROUT (of TC7662B) n (number of devices) V 1 2 C1 3 + 8 TC7662B 4 7 1 6 2 5 "1" C1 8 RL 7 TC7662B 3 "n" 4 6 5 + C2 Figure 5. Paralleling Devices Cascading Devices The TC7662B may be cascaded as shown to produce larger negative multiplication of the initial supply voltage. However, due to the finite efficiency of each device, the practical limit is 10 devices for light loads. The output voltage is defined by: VOUT = – n(VIN) V+ V+ 1 8 2 7 1 kΩ + 10µF where n is an integer representing the number of devices cascaded. The resulting output resistance would be approximately the weighted sum of the individual TC7662B ROUT values. 3 4 TC7662B CMOS GATE 6 5 VOUT + 10µF Figure 7. External Clocking It is also possible to increase the conversion efficiency of the TC7662B at low load levels by lowering the oscillator frequency. This reduces the switching losses, and is shown in Figure 8. However, lowering the oscillator frequency will cause an undesirable increase in the impedance of the pump (C1) and reservoir (C2) capacitors; this is overcome by increasing the values of C1 and C2 by the same factor that the frequency has been reduced. For example, the addition of a 100pF capacitor between pin 7 (Osc) and V+ will lower the oscillator frequency to 1kHz from its nominal frequency of 10kHz (multiple of 10), and thereby necessitate a corresponding increase in the value of C1 and C2 (from 10µF to 100µF). V+ 1 8 2 10µF + 7 3 TC7662B 6 4 "1" 5 1 8 2 10µF + 7 3 TC7662B 6 4 "n" 5 VOUT + *VOUT = –nV+ 10µF 10µF Figure 6. Cascading Devices for Increased Output Voltage © 2001 Microchip Technology Inc. DS21469A 5 TC7662B-8 9/11/96 CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B V+ V+ C1 + 1 8 2 7 3 TC7662B 4 COSC 6 1 8 2 7 TC7662B 3 5 VOUT + + C1 C2 D1 6 4 VOUT = – (V+– VF) 5 D2 + C3 VOUT = (2 V +) – (2 VF) + C2 Figure 8. Lowering Oscillator Frequency + C4 Positive Voltage Doubling Figure 10. Combined Negative Converter and Positive Doubler The TC7662B may be employed to achieve positive voltage doubling using the circuit shown in Figure 9. In this application, the pump inverter switches of the TC7662B are used to charge C1 to a voltage level of V+ – VF (where V+ is the supply voltage and VF is the forward voltage on C1 plus the supply voltage (V+) applied through diode D2 to capacitor C2). The voltage thus created on C2 becomes (2 V+) – (2 VF), or twice the supply voltage minus the combined forward voltage drops of diodes D1 and D2. The source impedance of the output (VOUT) will depend on the output current, but for V+ = 5V and an output current of 10 mA, it will be approximately 60Ω. Voltage Splitting The bidirectional characteristics can also be used to split a higher supply in half, as shown in Figure 11. The combined load will be evenly shared between the two sides and a high value resistor to the LV pin ensures start-up. Because the switches share the load in parallel, the output impedance is much lower than in the standard circuits, and higher currents can be drawn from the device. By using this circuit, and then the circuit of Figure 6, +15V can be converted (via +7.5V and –7.5V) to a nominal –15V, though with rather high series resistance (~250Ω). V+ V+ 1 8 2 7 3 4 TC7662B D1 D2 6 5 VOUT = (2 V+) – (2 VF) + + C1 C2 RL1 50 µF VOUT = V + –V – 2 + 50 µF + - 1 8 2 7 3 - 4 RL2 TC7662B 6 5 Figure 9. Positive Voltage Multiplier 50 µF Combined Negative Voltage Conversion and Positive Supply Multiplication V– Figure 10 combines the functions shown in Figures 3 and 9 to provide negative voltage conversion and positive voltage doubling simultaneously. This approach would be, for example, suitable for generating +9V and –5V from an existing +5V supply. In this instance, capacitors C1 and C3 perform the pump and reservoir functions, respectively, for the generation of the negative voltage, while capacitors C2 and C4 are pump and reservoir, respectively, for the doubled positive voltage. There is a penalty in this configuration which combines both functions, however, in that the source impedances of the generated supplies will be somewhat higher due to the finite impedance of the common charge pump driver at pin 2 of the device. TC7662B-8 9/11/96 + Figure 11. Splitting a Supply in Half 6 © 2001 Microchip Technology Inc. DS21469A CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B Regulated Negative Voltage Supply +5 LOGIC SUPPLY In some cases, the output impedance of the TC7662B can be a problem, particularly if the load current varies substantially. The circuit of Figure 12 can be used to overcome this by controlling the input voltage, via an ICL7611 low-power CMOS op amp, in such a way as to maintain a nearly constant output voltage. Direct feedback is advisable, since the TC7662B’s output does not respond instantaneously to change in input, but only after the switching delay. The circuit shown supplies enough delay to accommodate the TC7662B, while maintaining adequate feedback. An increase in pump and storage capacitors is desirable, and the values shown provide an output impedance of less than 5Ω to a load of 10mA. 1 8 2 7 + 1µF – 3 4 TC7662B 16 1 4 3 RS232 DATA OUTPUT 15 IH5142 13 6 14 5 +5V 1µF + -5V Figure 13. RS232 Levels from a Single 5V Supply – 50k 11 50k +8V 56k 12 TTL DATA INPUT +8V + – 10µF V+ + 100k 1 8 2 7 + 100µF 3 - TC7662B 5 4 800k 6 250K VOLTAGE ADJUST VOUT 100µF Figure 12. Regulating the Output Voltage © 2001 Microchip Technology Inc. DS21469A 7 TC7662B-8 9/11/96 CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B TYPICAL CHARACTERISTICS 1000 VOLTAGE CONVERSION EFFICIENCY (%) Supply Current vs. Temperature (with Boost Pin = VIN) 800 VIN = 12V IDD (µA) 600 400 200 VIN = 5V 0 -40 -20 0 20 40 60 80 Voltage Conversion 101.0 100.5 Without Load 100.0 99.5 10K Load 99.0 98.5 TA = 25°C 98.0 100 1 2 3 4 5 6 7 8 9 10 11 12 TEMPERATURE (°C) INPUT VOLTAGE VIN (V) Output Source Resistance vs. Supply Voltage Output Source Resistance vs. Temperature 100 OUTPUT SOURCE RESISTANCE (Ω) OUTPUT SOURCE RESISTANCE (Ω) 100 70 50 30 IOUT = 20mA TA = 25°C 10 1.5 2.5 3.5 4.5 5.5 6.5 7.5 8.5 9.5 10.5 11.5 12 VIN = 2.5V 80 60 VIN = 5.5V 40 20 0 -40 -20 SUPPLY VOLTAGE (V) Output Voltage vs. Output Current 200 20 40 60 80 100 Supply Current vs. Temperature 175 -2 SUPPLY CURRENT IDD (µA) OUTPUT VOLTAGE VOUT (V) 0 -4 -6 -8 -10 -12 0 TEMPERATURE (°C) 0 10 20 30 40 50 60 70 80 125 VIN = 12.5V 100 75 50 VIN = 5.5V 25 0 -40 90 100 OUTPUT CURRENT (mA) TC7662B-8 9/11/96 150 -20 0 20 40 60 80 100 TEMPERATURE (°C) 8 © 2001 Microchip Technology Inc. DS21469A CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B TYPICAL CHARACTERISTICS (cont.) Unloaded Osc Freq vs. Temperature with Boost Pin = VIN Unloaded Osc Freq vs. Temperature 60 OSCILLATOR FREQUENCY (kHz) OSCILLATOR FREQUENCY (kHz) 12 10 8 VIN = 5V 6 4 VIN = 12V 2 0 -40 -20 0 20 40 60 80 50 40 VIN = 5V 30 VIN = 12V 20 10 0 100 -40 -20 TEMPERATURE (°C) 0 20 40 60 80 100 TEMPERATURE (°C) PACKAGE DIMENSIONS 8-Pin Plastic DIP PIN 1 .260 (6.60) .240 (6.10) .045 (1.14) .030 (0.76) .070 (1.78) .040 (1.02) .310 (7.87) .290 (7.37) .400 (10.16) .348 (8.84) .200 (5.08) .140 (3.56) .040 (1.02) .020 (0.51) .150 (3.81) .115 (2.92) .110 (2.79) .090 (2.29) .015 (0.38) .008 (0.20) 3° MIN. .400 (10.16) .310 (7.87) .022 (0.56) .015 (0.38) Dimensions: inches (mm) © 2001 Microchip Technology Inc. DS21469A 9 TC7662B-8 9/11/96 CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B PACKAGE DIMENSIONS (Cont.) 8-Pin SOIC .157 (3.99) .150 (3.81) .244 (6.20) .228 (5.79) .050 (1.27) TYP. .197 (5.00) .189 (4.80) .069 (1.75) .053 (1.35) .010 (0.25) .007 (0.18) 8° MAX. .020 (0.51) .010 (0.25) .013 (0.33) .004 (0.10) .050 (1.27) .016 (0.40) Dimensions: inches (mm) TC7662B-8 9/11/96 10 © 2001 Microchip Technology Inc. DS21469A CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER TC7662B WORLDWIDE SALES AND SERVICE AMERICAS New York Corporate Office 150 Motor Parkway, Suite 202 Hauppauge, NY 11788 Tel: 631-273-5305 Fax: 631-273-5335 2355 West Chandler Blvd. Chandler, AZ 85224-6199 Tel: 480-792-7200 Fax: 480-792-7277 Technical Support: 480-792-7627 Web Address: http://www.microchip.com Rocky Mountain 2355 West Chandler Blvd. Chandler, AZ 85224-6199 Tel: 480-792-7966 Fax: 480-792-7456 ASIA/PACIFIC (continued) San Jose Microchip Technology Inc. 2107 North First Street, Suite 590 San Jose, CA 95131 Tel: 408-436-7950 Fax: 408-436-7955 Singapore Microchip Technology Singapore Pte Ltd. 200 Middle Road #07-02 Prime Centre Singapore, 188980 Tel: 65-334-8870 Fax: 65-334-8850 Taiwan Atlanta 6285 Northam Drive, Suite 108 Mississauga, Ontario L4V 1X5, Canada Tel: 905-673-0699 Fax: 905-673-6509 500 Sugar Mill Road, Suite 200B Atlanta, GA 30350 Tel: 770-640-0034 Fax: 770-640-0307 Microchip Technology Taiwan 11F-3, No. 207 Tung Hua North Road Taipei, 105, Taiwan Tel: 886-2-2717-7175 Fax: 886-2-2545-0139 ASIA/PACIFIC Austin EUROPE China - Beijing Australia Analog Product Sales 8303 MoPac Expressway North Suite A-201 Austin, TX 78759 Tel: 512-345-2030 Fax: 512-345-6085 Boston 2 Lan Drive, Suite 120 Westford, MA 01886 Tel: 978-692-3848 Fax: 978-692-3821 Boston Analog Product Sales Unit A-8-1 Millbrook Tarry Condominium 97 Lowell Road Concord, MA 01742 Tel: 978-371-6400 Fax: 978-371-0050 Toronto Microchip Technology Beijing Office Unit 915 New China Hong Kong Manhattan Bldg. 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No licenses are conveyed, implicitly or otherwise, except as maybe explicitly expressed herein, under any intellectual property rights. The Microchip logo and name are registered trademarks of Microchip Technology Inc. in the U.S.A. and other countries. All rights reserved. All other trademarks mentioned herein are the property of their respective companies. © 2001 Microchip Technology Inc. DS21469A 11 TC7662B-8 9/11/96