MC34163, MC33163 3.4 A, Step-Up/Down/ Inverting Switching Regulators The MC34163 series are monolithic power switching regulators that contain the primary functions required for dc−to−dc converters. This series is specifically designed to be incorporated in step−up, step−down, and voltage−inverting applications with a minimum number of external components. These devices consist of two high gain voltage feedback comparators, temperature compensated reference, controlled duty cycle oscillator, driver with bootstrap capability for increased efficiency, and a high current output switch. Protective features consist of cycle−by−cycle current limiting, and internal thermal shutdown. Also included is a low voltage indicator output designed to interface with microprocessor based systems. These devices are contained in a 16 pin dual−in−line heat tab plastic package for improved thermal conduction. http://onsemi.com MARKING DIAGRAMS 16 MC3x163P AWLYYWWG 16 PDIP−16 1 P SUFFIX CASE 648C 1 Features • • • • • • • • • • • • Output Switch Current in Excess of 3.0 A Operation from 2.5 V to 40 V Input Low Standby Current Precision 2% Reference Controlled Duty Cycle Oscillator Driver with Bootstrap Capability for Increased Efficiency Cycle−by−Cycle Current Limiting Internal Thermal Shutdown Protection Low Voltage Indicator Output for Direct Microprocessor Interface Heat Tab Power Package Moisture Sensitivity Level (MSL) Equals 1 Pb−Free Packages are Available* Ipk Sense 8 ILimit - 9 Driver Collector + VCC Timing Capacitor 10 7 + 6 4 GND 13 + 14 3 + + - 2 Switch Emitter VFB 1 SOIC−16W DW SUFFIX CASE 751G 1 x A WL YY WW G 1 = 3 or 4 = Assembly Location = Wafer Lot = Year = Work Week = Pb−Free Package PIN CONNECTIONS LVI Output 1 16 Bootstrap Input Voltage Feedback 2 2 15 Voltage Feedback 1 3 14 4 13 5 12 Timing Capacitor 6 11 VCC 7 10 Ipk Sense 8 9 Driver Collector Switch Emitter GND Switch Collector (Top View) 15 ORDERING INFORMATION LVI LVI Output MC3x163DW AWLYYWWG 16 GND 12 Control Logic and Thermal Shutdown GND Voltage Feedback 2 11 OSC 5 Voltage Feedback 1 Switch Collector 16 + + - 16 Bootstrap Input See detailed ordering and shipping information in the package dimensions section on page 2 of this data sheet. + *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. (Bottom View) This device contains 114 active transistors. Figure 1. Representative Block Diagram © Semiconductor Components Industries, LLC, 2008 August, 2008 − Rev. 6 1 Publication Order Number: MC34163/D MC34163, MC33163 MAXIMUM RATINGS (Note 1) Rating Symbol Value Unit VCC 40 V VC(switch) −1.0 to + 40 V Switch Emitter Voltage Range VE(switch) − 2.0 to VC(switch) V Switch Collector to Emitter Voltage VCE(switch) 40 V Switch Current (Note 2) ISW 3.4 A Driver Collector Voltage VC(driver) −1.0 to +40 V Driver Collector Current IC(driver) 150 mA IBS −100 to +100 mA VIpk (Sense) (VCC−7.0) to (VCC+1.0) V Vin −1.0 to + 7.0 V Low Voltage Indicator Output Voltage Range VC(LVI) −1.0 to + 40 V Low Voltage Indicator Output Sink Current IC(LVI) 10 Power Supply Voltage Switch Collector Voltage Range Bootstrap Input Current Range (Note 2) Current Sense Input Voltage Range Feedback and Timing Capacitor Input Voltage Range Thermal Characteristics P Suffix, Dual−In−Line Case 648C Thermal Resistance, Junction−to−Air Thermal Resistance, Junction−to−Case (Pins 4, 5, 12, 13) DW Suffix, Surface Mount Case 751G Thermal Resistance, Junction−to−Air Thermal Resistance, Junction−to−Case (Pins 4, 5, 12, 13) mA °C/W RqJA RqJC 80 15 RqJA RqJC 94 18 Operating Junction Temperature TJ +150 Operating Ambient Temperature (Note 3) MC34163 MC33163 TA Storage Temperature Range Tstg 0 to +70 − 40 to + 85 − 65 to +150 °C °C °C Maximum ratings are those values beyond which device damage can occur. Maximum ratings applied to the device are individual stress limit values (not normal operating conditions) and are not valid simultaneously. If these limits are exceeded, device functional operation is not implied, damage may occur and reliability may be affected. 1. This device series contains ESD protection and exceeds the following tests: Human Body Model 1500 V per MIL−STD−883, Method 3015. Machine Model Method 150 V. 2. Maximum package power dissipation limits must be observed. 3. Low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. ORDERING INFORMATION Package Shipping† MC33163DW SOIC−16W 47 Units / Rail MC33163DWG SOIC−16W (Pb−Free) 47 Units / Rail MC33163DWR2 SOIC−16W 1000 Units / Reel MC33163DWR2G SOIC−16W (Pb−Free) 1000 Units / Reel MC33163P PDIP−16 25 Units / Rail MC33163PG PDIP−16 (Pb−Free) 25 Units / Rail MC34163DW SOIC−16W 47 Units / Rail MC34163DWG SOIC−16W (Pb−Free) 47 Units / Rail MC34163DWR2 SOIC−16W 1000 Units / Reel MC34163DWR2G SOIC−16W (Pb−Free) 1000 Units / Reel MC34163P PDIP−16 25 Units / Rail MC34163PG PDIP−16 (Pb−Free) 25 Units / Rail Device †For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. http://onsemi.com 2 MC34163, MC33163 ELECTRICAL CHARACTERISTICS (VCC = 15 V, Pin 16 = VCC, CT = 620 pF, for typical values TA = 25°C, for min/max values TA is the operating ambient temperature range that applies (Note 5), unless otherwise noted.) Symbol Characteristic Min Typ Max 46 45 50 − 54 55 Unit OSCILLATOR fOSC Frequency TA = 25°C Total Variation over VCC = 2.5 V to 40 V, and Temperature Charge Current kHz Ichg − 225 − mA Idischg − 25 − mA Ichg/Idischg 8.0 9.0 10 − Sawtooth Peak Voltage VOSC(P) − 1.25 − V Sawtooth Valley Voltage VOSC(V) − 0.55 − V 4.9 − 4.85 5.05 0.008 − 5.2 0.03 5.25 V %/V V − 100 200 mA 1.225 − 1.213 1.25 0.008 − 1.275 0.03 1.287 V %/V V − 0.4 0 0.4 mA − 230 250 − − 270 − 1.0 20 − − 0.6 1.0 1.0 1.4 − 0.02 100 mA Discharge Current Charge to Discharge Current Ratio FEEDBACK COMPARATOR 1 Threshold Voltage TA = 25°C Line Regulation (VCC = 2.5 V to 40 V, TA = 25°C) Total Variation over Line, and Temperature Vth(FB1) Input Bias Current (VFB1 = 5.05 V) IIB(FB1) FEEDBACK COMPARATOR 2 Threshold Voltage TA = 25°C Line Regulation (VCC = 2.5 V to 40 V, TA = 25°C) Total Variation over Line, and Temperature Vth(FB2) Input Bias Current (VFB2 = 1.25 V) IIB(FB2) CURRENT LIMIT COMPARATOR Vth(Ipk Sense) Threshold Voltage TA = 25°C Total Variation over VCC = 2.5 V to 40 V, and Temperature Input Bias Current (VIpk (Sense) = 15 V) IIB(sense) mV mA DRIVER AND OUTPUT SWITCH (Note 4) Sink Saturation Voltage (ISW = 2.5 A, Pins 14, 15 grounded) Non−Darlington Connection (RPin 9 = 110 W to VCC, ISW/IDRV ≈ 20) Darlington Connection (Pins 9, 10, 11 connected) Collector Off−State Leakage Current (VCE = 40 V) VCE(sat) IC(off) Bootstrap Input Current Source (VBS = VCC + 5.0 V) V Isource(DRV) 0.5 2.0 4.0 mA VZ VCC + 6.0 VCC + 7.0 VCC + 9.0 V Vth 1.07 1.125 1.18 V Bootstrap Input Zener Clamp Voltage (IZ = 25 mA) LOW VOLTAGE INDICATOR Input Threshold (VFB2 Increasing) Input Hysteresis (VFB2 Decreasing) VH − 15 − mV Output Sink Saturation Voltage (Isink = 2.0 mA) VOL(LVI) − 0.15 0.4 V Output Off−State Leakage Current (VOH = 15 V) IOH − 0.01 5.0 mA ICC − 6.0 10 mA TOTAL DEVICE Standby Supply Current (VCC = 2.5 V to 40 V, Pin 8 = VCC, Pins 6, 14, 15 = GND, remaining pins open) 4. Low duty cycle pulse techniques are used during test to maintain junction temperature as close to ambient as possible. Thigh = + 70°C for MC34163 5. Tlow = 0°C for MC34163 = − 40°C for MC33163 = + 85°C for MC33163 http://onsemi.com 3 100 10 VCC = 15 V TA = 25°C 1)ton, RDT = ∞ 2)ton, RDT = 20 k 3)ton, toff, RDT = 10 k 4)toff, RDT = 20 k 5)toff, RDT = ∞ Δ f OSC, OSCILLATOR FREQUENCY CHANGE (%) t on -t off , OUTPUT SWITCH ON-OFF TIME ( μ s) MC34163, MC33163 1 2 3 4 5 1.0 0.1 1.0 CT, OSCILLATOR TIMING CAPACITOR (nF) 10 2.0 VCC = 15 V CT = 620 pF 0 -2.0 -4.0 -6.0 -55 -25 IIB , INPUT BIAS CURRENT (A) μ 140 VCC = 15 V VFB1 = 5.05 V 120 100 80 60 -55 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 125 V Z, BOOTSTRAP INPUT ZENER CLAMP VOLTAGE (V) I source (DRV), BOOTSTRAP INPUT CURRENT SOURCE (mA) Figure 4. Feedback Comparator 1 Input Bias Current versus Temperature 2.8 VCC = 15 V Pin 16 = VCC + 5.0 V 2.4 2.0 1.6 1.2 -55 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 100 125 Figure 3. Oscillator Frequency Change versus Temperature V th(FB2) , COMPARATOR 2 THRESHOLD VOLTAGE (mV) Figure 2. Output Switch On−Off Time versus Oscillator Timing Capacitor 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 125 1300 Vth Max = 1275 mV VCC = 15 V 1280 1260 Vth Typ = 1250 mV 1240 Vth Min = 1225 mV 1220 1200 -55 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 Figure 5. Feedback Comparator 2 Threshold Voltage versus Temperature 7.6 IZ = 25 mA 7.4 7.2 7.0 6.8 -55 Figure 6. Bootstrap Input Current Source versus Temperature -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 Figure 7. Bootstrap Input Zener Clamp Voltage versus Temperature http://onsemi.com 4 125 125 MC34163, MC33163 1.2 VCC -0.4 -0.8 Bootstrapped, Pin 16 = VCC + 5.0 V -1.2 -1.6 -2.0 Darlington Configuration Emitter Sourcing Current to GND Pins 7, 8, 10, 11 = VCC Pins 4, 5, 12, 13 = GND TA = 25°C, (Note 2) VCE (sat), SINK SATURATION (V) VCE (sat), SOURCE SATURATION (V) 0 Non-Bootstrapped, Pin 16 = VCC 0 0.8 1.6 2.4 IE, EMITTER CURRENT (A) 0.8 Grounded Emitter Configuration Collector Sinking Current From VCC Pins 7, 8 = VCC = 15 V Pins 4, 5, 12, 13, 14, 15 = GND TA = 25°C, (Note 2) Saturated Switch, RPin9 = 110 W to VCC 0.6 0.4 0.2 0 3.2 Darlington, Pins 9, 10, 11 Connected 1.0 GND 0 0.8 Figure 8. Output Switch Source Saturation versus Emitter Current V OL (LVI) , OUTPUT SATURATION VOLTAGE (V) V E , EMITTER VOLTAGE (V) -0.4 IC = 10 mA -0.8 IC = 10 mA -1.2 VCC = 15 V Pins 7, 8, 9, 10, 16 = VCC Pins 4, 6 = GND Pin 14 Driven Negative -1.6 -2.0 -55 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 125 0.5 VCC=5 V TA=25°C 0.4 0.3 0.2 0.1 0 0 2.0 4.0 6.0 Isink, OUTPUT SINK CURRENT (mA) 1.6 VCC = 15 V 252 250 248 246 -55 -25 8.0 Figure 11. Low Voltage Indicator Output Sink Saturation Voltage versus Sink Current IIB (Sense), INPUT BIAS CURRENT (μ A) V th (Ipk Sense) , THRESHOLD VOLTAGE (mV) Figure 10. Output Switch Negative Emitter Voltage versus Temperature 254 3.2 Figure 9. Output Switch Sink Saturation versus Collector Current 0 GND 1.6 2.4 IC, COLLECTOR CURRENT (A) 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 125 Figure 12. Current Limit Comparator Threshold Voltage versus Temperature VCC = 15 V VIpk (Sense) = 15 V 1.4 1.2 1.0 0.8 0.6 -55 -25 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) 100 125 Figure 13. Current Limit Comparator Input Bias Current versus Temperature http://onsemi.com 5 MC34163, MC33163 7.2 I CC, SUPPLY CURRENT (mA) 6.0 4.0 Pins 7, 8, 16 = VCC Pins 4, 6, 14 = GND Remaining Pins Open TA = 25°C 0 0 10 20 30 VCC, SUPPLY VOLTAGE (V) 6.4 5.6 4.8 4.0 -55 40 3.0 1.8 Pin 16 Open JUNCTION-TO-AIR ( °C/W) 2.2 Pin 16 = VCC 1.4 -25 0 25 50 75 100 80 5.0 RqJA 4.0 2.0 oz Copper L 3.0 mm Graphs represent symmetrical layout 3.0 2.0 40 PD(max) for TA = 70°C 20 0 125 L 60 0 10 20 1.0 30 40 0 50 L, LENGTH OF COPPER (mm) Figure 16. Minimum Operating Supply Voltage versus Temperature Figure 17. P Suffix (DIP−16) Thermal Resistance and Maximum Power Dissipation versus P.C.B. Copper Length 100 2.8 PD(max) for TA = 50°C 90 80 2.4 ÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎ ÎÎÎ ÎÎ Graph represents symmetrical layout 70 L 60 2.0 oz. Copper L 50 3.0 mm RqJA 40 10 2.0 1.6 1.2 0.8 0.4 30 0 125 Printed circuit board heatsink example TA, AMBIENT TEMPERATURE (°C) JUNCTION-TO-AIR ( °C/W) 1.0 -55 100 ÎÎÎÎÎ ÎÎÎÎÎ ÎÎÎÎÎ 100 R θ JA, THERMAL RESISTANCE 2.6 0 25 50 75 TA, AMBIENT TEMPERATURE (°C) Figure 15. Standby Supply Current versus Temperature CT = 620 pF Pins 7,8 = VCC Pins 4, 14 = GND Pin 9 = 1.0 kW to 15 V Pin 10 = 100 W to 15 V R θ JA, THERMAL RESISTANCE V CC(min) , MINIMUM OPERATING SUPPLY VOLTAGE (V) Figure 14. Standby Supply Current versus Supply Voltage -25 20 30 40 0 50 L, LENGTH OF COPPER (mm) Figure 18. DW Suffix (SOP−16L) Thermal Resistance and Maximum Power Dissipation versus P.C.B. Copper Length http://onsemi.com 6 P D , MAXIMUM POWER DISSIPATION (W) 2.0 VCC = 15 V Pins 7, 8, 16 = VCC Pins 4, 6, 14 = GND Remaining Pins Open PD, MAXIMUM POWER DISSIPATION (W) I CC, SUPPLY CURRENT (mA) 8.0 MC34163, MC33163 Ipk Sense RSC 7 VCC Timing Capacitor CT RDT Shutdown 0.25 V + 8 6 Current Limit + Switch Collector Oscillator 11 Q1 Q2 R Q S Latch 5 Thermal 4 12 60 GND 13 + 3 14 45 k Voltage Feedback 2 LVI Output Driver Collector 10 + GND Voltage Feedback 1 9 2 + + + - 1 LVI Switch Emitter Feedback Comparator + + - 15 2.0 mA 1.25 V 15 k + 1.125 V + 7.0 V 16 Bootstrap Input + - (Bottom View) Figure 19. Representative Block Diagram 1 Comparator Output 0 1.25 V Timing Capacitor CT 0.55 V t 9t 1 Oscillator Output 0 On Output Switch Off Nominal Output Voltage Level Output Voltage Startup Quiescent Operation Figure 20. Typical Operating Waveforms http://onsemi.com 7 = Sink Only Positive True Logic MC34163, MC33163 INTRODUCTION resistor increases the discharge current which reduces the on−time of the output switch. A graph of the Output Switch On−Off Time versus Oscillator Timing Capacitance for various values of RDT is shown in Figure 2. Note that the maximum output duty cycle, ton/ton + toff, remains constant for values of CT greater than 0.2 nF. The converter output can be inhibited by clamping CT to ground with an external NPN small−signal transistor. The MC34163 series are monolithic power switching regulators optimized for dc−to−dc converter applications. The combination of features in this series enables the system designer to directly implement step−up, step−down, and voltage−inverting converters with a minimum number of external components. Potential applications include cost sensitive consumer products as well as equipment for the automotive, computer, and industrial markets. A Representative Block Diagram is shown in Figure 19. Feedback and Low Voltage Indicator Comparators Output voltage control is established by the Feedback comparator. The inverting input is internally biased at 1.25 V and is not pinned out. The converter output voltage is typically divided down with two external resistors and monitored by the high impedance noninverting input at Pin 2. The maximum input bias current is ±0.4 mA, which can cause an output voltage error that is equal to the product of the input bias current and the upper divider resistance value. For applications that require 5.0 V, the converter output can be directly connected to the noninverting input at Pin 3. The high impedance input, Pin 2, must be grounded to prevent noise pickup. The internal resistor divider is set for a nominal voltage of 5.05 V. The additional 50 mV compensates for a 1.0% voltage drop in the cable and connector from the converter output to the load. The Feedback comparator’s output state is controlled by the highest voltage applied to either of the two noninverting inputs. The Low Voltage Indicator (LVI) comparator is designed for use as a reset controller in microprocessor−based systems. The inverting input is internally biased at 1.125 V, which sets the noninverting input thresholds to 90% of nominal. The LVI comparator has 15 mV of hysteresis to prevent erratic reset operation. The Open Collector output is capable of sinking in excess of 6.0 mA (see Figure 11). An external resistor (RLVI) and capacitor (CDLY) can be used to program a reset delay time (tDLY) by the formula shown below, where Vth(MPU) is the microprocessor reset input threshold. Refer to Figure 21. OPERATING DESCRIPTION The MC34163 operates as a fixed on−time, variable off−time voltage mode ripple regulator. In general, this mode of operation is somewhat analogous to a capacitor charge pump and does not require dominant pole loop compensation for converter stability. The Typical Operating Waveforms are shown in Figure 20. The output voltage waveform shown is for a step−down converter with the ripple and phasing exaggerated for clarity. During initial converter startup, the feedback comparator senses that the output voltage level is below nominal. This causes the output switch to turn on and off at a frequency and duty cycle controlled by the oscillator, thus pumping up the output filter capacitor. When the output voltage level reaches nominal, the feedback comparator sets the latch, immediately terminating switch conduction. The feedback comparator will inhibit the switch until the load current causes the output voltage to fall below nominal. Under these conditions, output switch conduction can be inhibited for a partial oscillator cycle, a partial cycle plus a complete cycle, multiple cycles, or a partial cycle plus multiple cycles. Oscillator The oscillator frequency and on−time of the output switch are programmed by the value selected for timing capacitor CT. Capacitor CT is charged and discharged by a 9 to 1 ratio internal current source and sink, generating a negative going sawtooth waveform at Pin 6. As CT charges, an internal pulse is generated at the oscillator output. This pulse is connected to the NOR gate center input, preventing output switch conduction, and to the AND gate upper input, allowing the latch to be reset if the comparator output is low. Thus, the output switch is always disabled during ramp−up and can be enabled by the comparator output only at the start of ramp−down. The oscillator peak and valley thresholds are 1.25 V and 0.55 V, respectively, with a charge current of 225 mA and a discharge current of 25 mA, yielding a maximum on−time duty cycle of 90%. A reduction of the maximum duty cycle may be required for specific converter configurations. This can be accomplished with the addition of an external deadtime resistor (RDT) placed across CT. The tDLY = RLVI CDLY In ǒ 1 Vth(MPU) 1− Vout Ǔ Current Limit Comparator, Latch and Thermal Shutdown With a voltage mode ripple converter operating under normal conditions, output switch conduction is initiated by the oscillator and terminated by the Voltage Feedback comparator. Abnormal operating conditions occur when the converter output is overloaded or when feedback voltage sensing is lost. Under these conditions, the Current Limit comparator will protect the Output Switch. http://onsemi.com 8 MC34163, MC33163 additional device heating and reduced conversion efficiency. Figure 10 shows that by clamping the emitter to 0.5 V, the collector current will be in the range 10 mA over temperature. A 1N5822 or equivalent Schottky barrier rectifier is recommended to fulfill these requirements. A bootstrap input is provided to reduce the output switch saturation voltage in step−down and voltage−inverting converter applications. This input is connected through a series resistor and capacitor to the switch emitter and is used to raise the internal 2.0 mA bias current source above VCC. An internal zener limits the bootstrap input voltage to VCC +7.0 V. The capacitor’s equivalent series resistance must limit the zener current to less than 100 mA. An additional series resistor may be required when using tantalum or other low ESR capacitors. The equation below is used to calculate a minimum value bootstrap capacitor based on a minimum zener voltage and an upper limit current source. The switch current is converted to a voltage by inserting a fractional ohm resistor, RSC, in series with VCC and output switch transistor Q2. The voltage drop across RSC is monitored by the Current Sense comparator. If the voltage drop exceeds 250 mV with respect to VCC, the comparator will set the latch and terminate output switch conduction on a cycle−by−cycle basis. This Comparator/Latch configuration ensures that the Output Switch has only a single on−time during a given oscillator cycle. The calculation for a value of RSC is: RSC + 0.25 V Ipk (Switch) Figures 12 and 13 show that the Current Sense comparator threshold is tightly controlled over temperature and has a typical input bias current of 1.0 mA. The propagation delay from the comparator input to the Output Switch is typically 200 ns. The parasitic inductance associated with RSC and the circuit layout should be minimized. This will prevent unwanted voltage spikes that may falsely trip the Current Limit comparator. Internal thermal shutdown circuitry is provided to protect the IC in the event that the maximum junction temperature is exceeded. When activated, typically at 170°C, the Latch is forced into the “Set” state, disabling the Output Switch. This feature is provided to prevent catastrophic failures from accidental device overheating. It is not intended to be used as a replacement for proper heatsinking. CB(min) + I Dt + 4.0 mA ton + 0.001 ton DV 4.0 V Parametric operation of the MC34163 is guaranteed over a supply voltage range of 2.5 V to 40 V. When operating below 3.0 V, the Bootstrap Input should be connected to VCC. Figure 16 shows that functional operation down to 1.7 V at room temperature is possible. Package The MC34163 is contained in a heatsinkable 16−lead plastic dual−in−line package in which the die is mounted on a special heat tab copper alloy lead frame. This tab consists of the four center ground pins that are specifically designed to improve thermal conduction from the die to the circuit board. Figures 17 and 18 show a simple and effective method of utilizing the printed circuit board medium as a heat dissipater by soldering these pins to an adequate area of copper foil. This permits the use of standard layout and mounting practices while having the ability to halve the junction−to−air thermal resistance. These examples are for a symmetrical layout on a single−sided board with two ounce per square foot of copper. Driver and Output Switch To aid in system design flexibility and conversion efficiency, the driver current source and collector, and output switch collector and emitter are pinned out separately. This allows the designer the option of driving the output switch into saturation with a selected force gain or driving it near saturation when connected as a Darlington. The output switch has a typical current gain of 70 at 2.5 A and is designed to switch a maximum of 40 V collector to emitter, with up to 3.4 A peak collector current. The minimum value for RSC is: RSC(min) + 0.25 V + 0.0735 W 3.4 A APPLICATIONS When configured for step−down or voltage−inverting applications, as in Figures 21 and 25, the inductor will forward bias the output rectifier when the switch turns off. Rectifiers with a high forward voltage drop or long turn−on delay time should not be used. If the emitter is allowed to go sufficiently negative, collector current will flow, causing The following converter applications show the simplicity and flexibility of this circuit architecture. Three main converter topologies are demonstrated with actual test data shown below each of the circuit diagrams. http://onsemi.com 9 MC34163, MC33163 0.25 V + 8 RSC Vin 12 V 0.075 7 + Cin 330 9 10 + 6 CT 680 pF Current Limit + Oscillator 11 Q1 Thermal 4 Q2 R Q S Latch 5 12 60 13 + 3 14 45 k 2 RLVI 10 k Low Voltage Indicator Output 1 CDLY + + - + LVI Feedback Comparator 1N5822 0.02 2.0 mA 1.25 V 15 k + 1.125 V + + - 15 16 + 7.0 V CB L 2200 (Bottom View) Test RB Condition 180 mH Coilcraft LO451-A Vout + 5.05 V/3.0 A CO Results Line Regulation Vin = 8.0 V to 24 V, IO = 3.0 A 6.0 mV = ± 0.06% Load Regulation Vin = 12 V, IO = 0.6 A to 3.0 A 2.0 mV = ± 0.02% Output Ripple Vin = 12 V, IO = 3.0 A 36 mVpp Short Circuit Current Vin = 12 V, RL = 0.1 W 3.3 A Efficiency, Without Bootstrap Vin = 12 V, IO = 3.0 A 76.7% Efficiency, With Bootstrap Vin = 12 V, IO = 3.0 A 81.2% Figure 21. Step−Down Converter 8 7 + 6 Q1 Q2 5 4 + 9 8 10 7 11 6 12 5 13 4 11 Q1 Q2 12 13 + 14 15 2 15 16 1 14 2 Q3 + Q3 10 + 3 3 1 9 16 + (Bottom View) (Bottom View) Figure 22A. External NPN Switch Figure 22B. External PNP Saturated Switch Figure 22. External Current Boost Connections for Ipk (Switch) Greater Than 3.4 A http://onsemi.com 10 MC34163, MC33163 0.25 V + 8 RSC 0.075 Vin 12 V Cin + 7 Current Limit + L 9 180 mH Coilcraft LO451-A 10 + 330 6 Oscillator CT 680 pF 11 Q1 Thermal 4 Q2 R Q S Latch 5 12 60 13 + 1N5822 3 14 45 k 2 Low Voltage Indicator Output 1 RLVI 1.0 k R1 2.2 k + + - + LVI + + - Feedback Comparator 1.25 V 15 k + 1.125 V R2 47 k 15 2.0 mA 16 7.0 V + Vout 28 V/600 mA +C O (Bottom View) 330 Test Condition Results Line Regulation Vin = 9.0 V to 16 V, IO = 0.6 A 30 mV = ± 0.05% Load Regulation Vin = 12 V, IO = 0.1 A to 0.6 A 50 mV = ± 0.09% Output Ripple Vin = 12 V, IO = 0.6 A 140 mVpp Efficiency Vin = 12 V, IO = 0.6 A 88.1% Figure 23. Step−Up Converter 8 7 + 6 Q1 Q2 5 4 + 9 8 10 7 11 6 12 5 13 4 3 14 2 1 9 10 + 11 Q1 Q2 12 13 + 3 14 15 2 15 16 1 Q3 + Q3 16 + (Bottom View) (Bottom View) Figure 24A. External NPN Switch Figure 24B. External NPN Saturated Switch Figure 24. External Current Boost Connections for Ipk (Switch) Greater Than 3.4 A http://onsemi.com 11 MC34163, MC33163 0.25 V + 8 RSC Vin 12 V 0.075 Cin 330 Current Limit + 9 7 + 10 + 6 CT 470 pF Oscillator 11 Q1 Q2 R Q S Latch 5 Thermal 4 12 60 13 + Coilcraft LO451-A 3 14 L 180 mH 45 k 2 + 1 LVI R2 8.2 k + + - Feedback Comparator 1.25 V 15 k + 1.125 V + + - R1 953 15 0.02 2.0 mA 16 + 7.0 V 1N5822 2200 (Bottom View) Test RB CB Vout -12 V/1.0 A + CO Condition Results Line Regulation Vin = 9.0 V to 16 V, IO = 1.0 A 5.0 mV = ± 0.02% Load Regulation Vin = 12 V, IO = 0.6 A to 1.0 A 2.0 mV = ± 0.01% Output Ripple Vin = 12 V, IO = 1.0 A 130 mVpp Short Circuit Current Vin = 12 V, RL = 0.1 W 3.2 A Efficiency, Without Bootstrap Vin = 12 V, IO = 1.0 A 73.1% Efficiency, With Bootstrap Vin = 12 V, IO = 1.0 A 77.5% Figure 25. Voltage−Inverting Converter 8 7 + 6 Q1 Q2 9 8 10 7 11 6 9 10 + 11 Q1 Q2 12 5 13 4 3 14 3 14 2 15 2 15 5 4 + Q3 16 1 12 13 + 16 1 + Q3 + (Bottom View) (Bottom View) Figure 26A. External NPN Switch Figure 26B. External PNP Saturated Switch Figure 26. External Current Boost Connections for Ipk (Switch) Greater Than 3.4 A http://onsemi.com 12 MC34163, MC33163 + + + + VO - + CT L C in R1 RB - R LVI V in CB + R2 MC34163 Step−Down CO + + R SC + + Bottom View + + Top View + + + - - R LVI V in VO + L C in R1 + R2 MC34163 Step−Up + CO + + CT + R SC + + Bottom View + + Top View + + VO + - CB + RB - R1 V in + + + + Bottom View CT L C in + R2 CO MC34163 Voltage−Inverting + R SC Top View All printed circuit boards are 2.58” in width by 1.9” in height. Figure 27. Printed Circuit Board and Component Layout (Circuits of Figures 21, 23, 25) http://onsemi.com 13 + MC34163, MC33163 Step−Down Calculation ton (Notestoff 1, 2, 3) V Step−Up V out ) V F * V sat * V out in ǒ ton ƒ t on t off V Ǔ t on ) 1 t off IL(avg) ƒ ǒ L Vripple(pp) V L 2 DIL DI ǒ 1 8 ƒCO ref ǒ L Ǔ 2 R2 R1 t on t off V Ǔ t on ) 1 t off ƒ ǒ Ǔ t on ) 1 t off IL(avg) ) Ǔ ǒ t on V ) (ESR)2 DI L 2 [ Ǔ ) 1 V ref ǒ R2 R1 Ǔ t on ) 1 t off ǒ Ǔ t on ) 1 t off IL(avg) ) t on ǒ V t on I out C t on t off DI L 2 0.25 Ipk (Switch) Ǔ L ǒ I out DI * V sat in F * V sat in 32.143 · 10 6 ƒ 0.25 Ipk (Switch) * V sat * V out in V Vout DI 0.25 Ipk (Switch) RSC in ǒ I out IL(avg) ) V F in V sat 32.143 · 10 6 ƒ Iout Ipk (Switch) |V out| ) V V out ) V 32.143 · 10 6 ƒ CT Voltage−Inverting in Ǔ ) 1 V ref L t on t on I out [ O Ǔ * V sat DI C ǒ R2 R1 O Ǔ ) 1 The following Converter Characteristics must be chosen: Nominal operating input voltage. Desired output voltage. Desired output current. Desired peak−to−peak inductor ripple current. For maximum output current it is suggested that DIL be chosen to be less than 10% of the average inductor current IL(avg). This will help prevent Ipk (Switch) from reaching the current limit threshold set by RSC. If the design goal is to use a minimum inductance value, let DIL = 2(IL(avg)). This will proportionally reduce converter output current capability. p − Maximum output switch frequency. Vripple(pp) − Desired peak−to−peak output ripple voltage. For best performance the ripple voltage should be kept to a low value since it will directly affect line and load regulation. Capacitor CO should be a low equivalent series resistance (ESR) electrolytic designed for switching regulator applications. Vin − Vout − Iout − DIL − NOTES: NOTES: NOTES: NOTES: 1. 2. 3. 3. Vsat − Saturation voltage of the output switch, refer to Figures 8 and 9. VF − Output rectifier forward voltage drop. Typical value for 1N5822 Schottky barrier rectifier is 0.5 V. The calculated ton/toff must not exceed the minimum guaranteed oscillator charge to discharge ratio of 8, at the minimum operating input voltage. Figure 28. Design Equations http://onsemi.com 14 MC34163, MC33163 PACKAGE DIMENSIONS PDIP−16 P SUFFIX CASE 648C−04 ISSUE D A T B B K C N F T E G 16X SEATING PLANE D 0.005 (0.13) M T A http://onsemi.com 15 0.005 (0.13) J 8 16X 1 L 9 B 16 M M A NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: INCH. 3. DIMENSION L TO CENTER OF LEADS WHEN FORMED PARALLEL. 4. DIMENSION B DOES NOT INCLUDE MOLD FLASH. DIM A B C D E F G J K L M N INCHES MIN MAX 0.744 0.783 0.240 0.260 0.145 0.185 0.015 0.021 0.050 BSC 0.040 0.70 0.100 BSC 0.008 0.015 0.115 0.135 0.300 BSC 0_ 10_ 0.015 0.040 MILLIMETERS MIN MAX 18.90 19.90 6.10 6.60 3.69 4.69 0.38 0.53 1.27 BSC 1.02 1.78 2.54 BSC 0.20 0.38 2.92 3.43 7.62 BSC 0_ 10_ 0.39 1.01 MC34163, MC33163 PACKAGE DIMENSIONS SOIC−16W DW SUFFIX CASE 751G−03 ISSUE C A D 9 h X 45 _ E 0.25 H 8X M B M 16 q 1 NOTES: 1. DIMENSIONS ARE IN MILLIMETERS. 2. INTERPRET DIMENSIONS AND TOLERANCES PER ASME Y14.5M, 1994. 3. DIMENSIONS D AND E DO NOT INLCUDE MOLD PROTRUSION. 4. MAXIMUM MOLD PROTRUSION 0.15 PER SIDE. 5. DIMENSION B DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.13 TOTAL IN EXCESS OF THE B DIMENSION AT MAXIMUM MATERIAL CONDITION. MILLIMETERS DIM MIN MAX A 2.35 2.65 A1 0.10 0.25 B 0.35 0.49 C 0.23 0.32 D 10.15 10.45 E 7.40 7.60 e 1.27 BSC H 10.05 10.55 h 0.25 0.75 L 0.50 0.90 q 0_ 7_ 8 16X M 14X e T A S B S A1 L A 0.25 B B SEATING PLANE T C ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. 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