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| SMP402 1-Watt Buck Regulator IC 20-72 VDC Input Non-isolated DC Output Product Highlights Integrated Power Switch and CMOS Controller * Output power > 1 W from 48 VDC input * Adjustable output voltage * Integrated solution minimizes overall size High-voltage, Low-capacitance MOSFET Output * Designed for ISDN T1 telecommunications applications * Low capacitance allows for high frequency operation High-voltage Buck Regulator * Internal pre-regulator self-powers the IC on start-up * Designed for low power consumption * Minimum external parts required Built-In Self-protection Circuits * Undervoltage lockout * Thermal shutdown * Input polarity/level sense SMP402 + 48 VDC - (R) + 5 VDC - PI-555A-123091 Figure 1. Typical Application. Description The SMP402, intended for non-isolated ISDN telecommunications power supply applications, combines a high voltage power MOSFET switch with a switchmode power system controller in a monolithic integrated circuit. Few external components are required to implement a low cost power supply which meets stringent ISDN specifications. High frequency operation reduces total power supply size. The P-channel power MOSFET switch features include high voltage, low RDS(ON), and low capacitance. Lower capacitance results in a reduction in gate drive power, and also facilitates higher frequency operation. The controller section of the SMP402 contains all the blocks required to drive and control the power stage: start-up preregulator circuit, oscillator, bandgap reference, error amplifier, gate driver and level shift. Protection features include undervoltage lockout, thermal shutdown, and input polarity and level sensing. The SMP402 is available in a 16-pin plastic SOIC package. VIN VLS ENABLE D GND A GND SENSE+ SENSE REXT 1 2 3 4 5 6 7 8 16 15 14 13 12 11 10 9 OUT POLARITY LEVEL VS EA IN EA OUT VBIAS CEXT PI-553B-012892 Figure 2. Pin Configuration. ORDERING INFORMATION PART NUMBER SMP402SC PACKAGE OUTLINE S16A Tj RANGE 0 to 120C January 1996 SMP402 VIN VLS ENABLE VBIAS VS A GND REXT D GND S CEXT EA OUT + OUT HV REG UV LOCKOUT VREF BANDGAP REF THERMAL SHUTDOWN LEVEL SHIFT Q S R Q OSC + - R PWM COMPARATOR EA IN - ERROR AMPLIFIER 4V + VS 23 A 5 A VS SENSE+ LEVEL POLARITY VS 23 A 5 A VS SENSE- PI-552B-062293 Figure 3. Functional Block Diagram. 2 D 1/96 SMP402 Pin Functional Description Pin 1: VIN is the high-voltage input to the switching regulator. This is the Source connection of the P-Channel power MOSFET pass transistor. Pin 2: VLS is an internal supply for the level shift circuit that drives the P-Channel MOSFET. A capacitor should be placed between VLS and VIN for bypassing. V LS is normally 10 V below VIN . Pin 3: The power supply can be shut down by pulling ENABLE low. Pin 4: D GND is the common return point for the power and logic portions of the circuit. Pin 5: A GND is the common return point. REXT and CEXT are directly connected to this point. Pin 6: The SENSE+ input monitors the polarity and level of the input voltage through an external resistor for ISDN emergency standby sensing. Pin 7: The SENSE- input monitors the polarity and level of the input voltage through an external resistor for ISDN emergency standby sensing. Pin 8: A 20.5 k resistor connected between REXT and A GND sets the internal bias currents including oscillator charge and discharge currents. Pin 9: The oscillator frequency can be programmed by selecting the value of the capacitor connected between CEXT and A GND. Pin 10: VBIAS can be connected to the output 5 V rail of the converter to reduce power dissipation. The internal 5 V regulator is cut off when the output is in regulation. Pin 11: EA OUT is the error amplifier output pin for connection to the external compensation network. Pin 12: EA IN is the error amplifier negative input for connection to the feedback and compensation networks. Pin 13: VS is the internal supply voltage. This pin is brought out for external bypassing. Pin 14: The LEVEL output indicates when the input voltage is in its normal operating range. Pin 15: The POLARITY output is used to notify a microprocessor of an emergency standby condition for ISDN applications. Pin 16: OUT is the Drain connection of the PChannel pass transistor. Functional Description High Voltage Regulator The high-voltage regulator provides the bias current required by the controller and driver circuitry. The pre-regulator consists of a high voltage MOSFET, a gate bias current source, and an error amplifier. The error amplifier regulates VS to approximately 5 V by controlling the gate of the MOSFET. In 5 V output applications, the control circuitry may also be operated by connecting the VBIAS pin to the output 5 V rail of the converter to reduce power dissipation. The internal 5 V regulator is cut off automatically when the converter output is in regulation. Only the supply current for the level shift stage (50 A) and the AC switching currents for the PChannel output device are drawn from the VIN supply under this condition. If unused, VBIAS must be hardwired to A GND to disable the automatic switchover during power-up. VLS is the level-shift supply for driving the gate of the internal P-channel MOSFET. The voltage at V LS is approximately 10 V below VIN. VS is the supply voltage for the controller and driver circuitry. External bypass capacitors connected to VLS and VS are required for filtering and reducing noise. UV Lockout During power-up, the undervoltage lockout circuit keeps the P-channel output transistor in the off state until the internal VS supply is in regulation and the voltage sensed by the input monitor circuit is within the normal operation range (>12 V). Band Gap Reference VREF is the 1.3 V reference voltage generated by the temperaturecompensated bandgap reference and buffer. This voltage is used for setting thresholds for the error amplifier and over temperature circuit. D 1/96 3 SMP402 Functional Description (cont.) Oscillator The oscillator frequency can be adjusted by changing the external CEXT capacitor. This capacitor is charged and discharged by switched constant current sources. The voltage switch points are determined by hysteresis built into a comparator. The period of the waveform is determined by values of the current sources which set the rising and falling slopes of the sawtooth waveform. Maximum duty cycle is equal to the ratio of the charge time to the period. Clock and blanking signals are synthesized from the comparator output for use by the modulator. Error Amplifier The error amplifier consists of a high performance operational amplifier with the non-inverting input connected to the internal bandgap reference voltage. The output of the error amplifier directly controls the duty cycle of the power switch. Pulse Width Modulator The pulse width modulator implements a voltage-mode control loop, and generates the digital driver signal which controls the power switch. The duty cycle of the driver signal will change as a function of input voltage and load. Increasing the duty cycle causes the power supply output voltage to go up. Conversely, decreasing the duty cycle causes the output voltage to go down. The pulse width modulator compares the control voltage (error amplifier output) with the sawtooth voltage generated by the oscillator to produce the required duty cycle. Thermal Shutdown Temperature protection is provided by a precision analog circuit that turns the power switch off when the junction gets too hot (typically 140C). The device will automatically reset and turn back on again when the junction has cooled past the hysteresis temperature level. SENSE+ and SENSE- Inputs SENSE+ and SENSE-are both current mirror inputs consisting of N-channel MOSFETs connected as diodes. The threshold voltage of each transistor is typically 1.7 V. An input current which exceeds the indicated threshold current will turn on the mirror transistor for an active-low signal. POLARITY and LEVEL Outputs The LEVEL output is high when the input current to either SENSE+ or SENSE- exceeds the LEVEL current threshold and the output voltage is in regulation. During normal operation, the POLARITY output is high when the input current to SENSE+ is above the POLARITY current threshold and the output voltage is in regulation. During emergency operation (when the DC input voltage is inverted), the POLARITY output is low when the input current to SENSE- exceeds the 48 V 32 V 30 V 12 V 10 V INPUT 0 -10 V -32 V -48 V -30 V 5 V OUT LEVEL POLARITY 5V 0V 5V 0V 5V 0V PI-960A-032293 Figure 4. Turn-on and Turn-off Waveforms of the SMP402. 4 D 1/96 SMP402 Functional Description (cont.) POLARITY current threshold. Regulation of the output voltage is detected by a comparator which looks for error amplifier saturation in the output high (maximum duty cycle) state. Power supply turn on and turn off with a slowly changing input voltage is shown in Figure 4 as measured using the circuit shown in Figure 6. Also shown are the level and polarity outputs. The input voltage must rise above 32 V before the SMP402 will turn on. At this input voltage the current through R1 into the SENSE+ input exceeds the threshold current (typically 23 A), the LEVEL and POLARITY outputs go high, and the power supply turns on. As the input voltage goes down, LEVEL will go low at approximately 30 V, but POLARITY will stay high. As the input voltage continues to drop, POLARITY goes low at approximately 12 V and the converter loses regulation at approximately 10 V and turns off. The LEVEL output will go high and the power supply turns on when the input voltage reaches -32 V. POLARITY stays low to indicate that the input voltage has reversed polarity. As the negative input voltage falls toward zero, LEVEL goes low at approximately -30 V and the converter loses regulation and turns off at approximately -10 V. Enable The power supply can be shut down by pulling the ENABLE pin low. It is internally pulled up to VS with a 100 A (nominal) current source. However, it is recommended that this pin be tied to VS if it is unused. P-Channel Output Transistor The output MOSFET is a 90 V pass transistor capable of supplying >200 mA. To minimize switching noise and EMI, it is important to keep the path from OUT through the output diode, the input storage capacitor, and into VIN as short as possible. INPUT VOLTAGE CONDITION Negative voltage, level too low Negative voltage, correct level Positive voltage, level too low Positive voltage, correct level POLARITY 0 0 1 1 LEVEL 0 1 0 1 Figure 5. LEVEL/POLARITY Truth Table. The LEVEL and POLARITY signals are only valid when the output voltage is in regulation. D 1/96 5 SMP402 L1 470 H + INPUT D1 D2 C1 4X 1N4002 D3 D4 R1 1.2 M C5 100 nF 1 2 3 4 5 6 7 8 R3 20.5 k U1 16 15 14 13 12 11 10 9 C11 120 pF JMP 1 VOUT R5 75 k D6 UF4002 C2 82 F C6 100 nF SMP402SC RTN POLARITY LEVEL C4-1 nF C3 100 nF R4 240 k R2 1.2 M R7 3.3 M R8 3.3 M R6 24.9 k PI-1455-042695 Figure 6. Schematic Diagram of a Non-isolated 5 V, 1 W ISDN Regulator Circuit Utilizing the SMP402. General Circuit Operation The Buck DC-to-DC converter shown in Figure 6 produces a single non-isolated 5 V, 1 W power supply. The highvoltage P-channel MOSFET transistor in the SMP402 is turned on and off at the switching frequency. The ratio of ONtime to the switching period is defined as the duty cycle. The duty cycle changes with input voltage to maintain a constant average value of the switching waveform. The switching waveform is filtered by inductor L1 and capacitor C2 to produce the 5 V output. During the MOSFET ON-time, the switch current and inductor current ramp up at a linear rate. During the P channel MOSFET switch off time, the voltage across L1 reverses, forward biasing D6. Inductor and diode current then ramp down linearly until the MOSFET turns on again. During normal operation, inductor current ramps up and down around the average value (IOUT), which is actually the DC load current. The 5 V output voltage is directly sensed and accurately regulated by an internal error amplifier. The error amplifier generates an error signal which directly controls the duty cycle of the integrated high-voltage P-channel MOSFET switch. The effective output voltage can be fine-tuned by adjusting the resistor divider formed by R5 and R6. Other output voltages are possible (up to approximately half the input voltage) by changing the value of L1 as well as the resistor divider. Polarity of the DC input voltage can be either positive or negative. D1, D2, D3, and D4 "rectify" the DC input voltage to provide a positive polarity input voltage for the converter. C1 provides input voltage filtering. The SMP402 contains the integrated controller and high-voltage P-channel MOSFET which, together with D6, generates a pulse width modulated switching AC voltage waveform. L1 and C2 filter the AC voltage to create the 5 V output. C6 filters high-frequency noise currents. R5 and R6 sense and divide the 5 V output voltage for comparison with the internal bandgap reference voltage. C4 and R4 provide control loop compensation feedback around the internal error amplifier. C3 bypasses the onboard VS regulator. C11 sets the switching frequency. R3 is fixed to set internal currents accurately. C5 bypasses an internally-generated, level-shifted bias source of approximately 10 V, which is referenced to the positive side of the effective input voltage. This floating supply is used for biasing the P-channel MOSFET gate drivers. R1 and R2 sense the level and polarity of the DC input voltage. The current through R1 and the SENSE+ input or R2 and the SENSEinput must exceed 23 A before the converter will turn on. R7 and R8 provide hysteresis for the SENSE+ and SENSE- inputs. Jumper JMP1 disables the self-bias feature of the SMP402. 6 D 1/96 SMP402 General Circuit Operation (cont.) The line and load regulation graphs were measured on the circuit shown in Figure 6. The switching frequency of the power supply was measured at 230 kHz. The maximum output power curve shows the power output capability for a 470 H output filter inductor (L1). The output power versus frequency curve was generated by characterization of the SMP402 at various frequencies. The curve demonstrates the trade-off between AC and DC power losses within the device. As AC losses rise with frequency, DC losses and output power must be reduced to maintain the same device maximum power dissipation. Typical Performance Characteristics (Figure 6 Power Supply) LINE REGULATION PI-939A-031393 LOAD REGULATION Output Voltage (% of Nominal) PI-938-022293 MAXIMUM OUTPUT POWER TA = 25C PI-940-022293 105 105 2.0 Output Voltage (% of Nominal) 104 104 Output Power (W) VIN = 48 VDC 0 100 200 300 400 500 1.5 103 103 1.0 102 102 101 ILOAD = 200 mA 0 20 40 60 80 101 0.5 100 100 0 0 20 40 60 80 Input Voltage (VDC) Load Current (mA) Input Voltage (VDC) EFFICIENCY vs. OUTPUT POWER PI-950-022593 EFFICIENCY vs. INPUT VOLTAGE PI-944-022293 OUTPUT POWER vs. FREQUENCY TA = 25C VIN = 48 VDC PI-951-022593 80 5 V Output Efficiency (%) Output Efficiency (%) 60 60 Output Power (W) 70 VIN = 24 VDC VIN = 48 VDC VIN = 72 VDC 80 2 ILOAD = 200 mA 70 1 50 50 40 40 0 30 0 1 2 30 0 20 40 60 80 0 100 200 300 400 500 Load Power (W) Input Voltage (VDC) Switching Frequency (kHz) D 1/96 7 SMP402 ABSOLUTE MAXIMUM RATINGS1 VIN Voltage .................................................................. 80 V Drain-Source Voltage (V IN to OUT) ........................... 90 V VBIAS Voltage .............................................................. 5.5 V SENSE Current .................................................... 200 A OUT Voltage ........................................ VIN + 0.3 V to -4 V OUT Current ..........................................................250 mA Logic Input Voltage ........................... -0.3 V to VS + 0.3 V Storage Temperature ..................................... -65 to 125C Operating Junction Temperature(2). ................... 0 to 150C Lead Temperature (3). ................................................ 260C Power Dissipation ..................................................... 1.0 W Thermal Impedance (JA) ...................................... 55C/W Thermal Impedance (JC)(4) .................................... 15C/W 1. 2. 3. 4. Unless noted, all voltages referenced to A GND, TA=25C Normally limited by internal circuitry. 1/16" from case for 5 seconds. Measured at pin 4/5. Conditions Parameter Symbol (Unless Otherwise Specified) V IN = 48 V, V BIAS = 5 V, GNDs = 0 V REXT = 20.5 k, CEXT = 120 pF RS+, RS- = 1.2 M, T j = 0 to 120C Min Typ Max Units OSCILLATOR Output Frequency Initial Accuracy fOSC fOSC CEXT = 30 to 300 pF 50 500 kHz 200 230 260 kHz PULSE WIDTH MODULATOR Duty Cycle ERROR AMPLIFIER Threshold Voltage Gain-Bandwidth Product DC Gain Common-mode Range Output Impedance AVOL VEA IN ZOUT See Note 2 60 VREF 1.22 1.32 V DC 0-50 0-70 % 0.5 MHz 80 dB 0 3 V 1 k 8 D 1/96 SMP402 Conditions Parameter Symbol (Unless Otherwise Specified) VIN = 48 V, VBIAS = 5 V, GNDs = 0 V REXT = 20.5 k, CEXT = 120 pF RS+, RS- = 1.2 M, Tj = 0 to 120C Min Typ Max Units CIRCUIT PROTECTION Thermal Shutdown Temperature Thermal Shutdown Hysteresis LOGIC Input Current High Input Current Low Input Voltage High Input Voltage Low Output Voltage High Output Voltage Low SENSE INPUTS Threshold Voltage LEVEL Threshold Current POLARITY Threshold Current OUTPUT ON-State Resistance ON-State Current RDS(ON) ID(ON) IOUT = -100 mA VDS = 5 V See Note 1 Tj = 25C Tj = 100C Tj = 25C Tj = 100C 200 100 500 350 mA 12 20 V SENSE+/ILEVEL IPOLARITY 21 1.7 2.2 V A A IIH IIL VIH VIL V OH VOL IOH = -0.5 mA IOL = 0.5 mA 1.0 -500 10 50 A A VIH = 3.0 V VIL = 0 V 120 140 C C 15 -100 3.0 V V 3.5 V 0.4 V 24 27 5 7 D 1/96 9 SMP402 Conditions Parameter Symbol (Unless Otherwise Specified) V IN = 48 V, V BIAS = 5 V, GNDs = 0 V REXT = 20.5 k, CEXT = 120 pF RS+, RS- = 1.2 M, T j = 0 to 120C Min Typ Max Units OUTPUT (cont.) OFF-State Current Breakdown Voltage SUPPLY HV Regulator Voltage Off-line Supply Current VBIAS Supply Voltage VBIAS Supply Current VIN IIN VBIAS = A GND VBIAS = 5 V 4.75 12 1.5 1 72 2.5 1.5 5.25 mA V IDSS BVDSS VIN = 72 V, OUT = 0 V, TA = 120C IOUT = -250 A, TA = 25C -50 -10 A 90 V VBIAS IBIAS V 1 1.5 mA NOTES: 1. At low output currents (< 20 mA), the part may operate in blocking oscillation mode, resulting in large output ripple. 2. Applying >3.5 V to the EA IN pin activates an internal test circuit that turns on the output switch continuously. Destruction of the part can occur if the output of the SMP402 is connected to a high voltage power source when the test circuit is activated. 470 H 100 nF C1 U1 75 k 82 F UF4002 16 15 14 13 12 11 10 9 120 pF 100 nF 152 48 VDC R1 1.2 M 1.2 M 1 2 3 4 5 6 7 8 20.5 k SMP402SC 1 nF 240 k 24.9 k 100 nF PI-1456-042695 Figure 7. Switching Time Test Circuit. 10 D 1/96 SMP402 BREAKDOWN vs. TEMPERATURE PI-176B-051391 fPWM vs. EXTERNAL CAPACITANCE PI-1011-051793 1.1 500 Breakdown Voltage (V) (Normalized to 25C) PWM Frequency (kHz) 400 300 1.0 200 100 0.9 -50 -25 0 25 50 75 100 125 150 0 0 100 200 300 400 500 Junction Temperature (C) External Capacitance (pF) COSS vs. DRAIN VOLTAGE PI-1008-051093 DRAIN CHARGE vs. DRAIN VOLTAGE PI-942-022293 100 3.0 2.5 Drain Capacitance (pF) Drain Charge (nC) 0 20 40 60 80 80 2.0 1.5 1.0 0.5 0 0 20 40 60 80 60 40 20 0 Drain Voltage (V) Drain Voltage (V) DRAIN CAPACITANCE ENERGY PI-941-022293 60 50 Energy (nJ) 40 30 20 10 0 0 20 40 60 80 Drain Voltage (V) D 1/96 11 SMP402 PACKAGE POWER DERATING PI-1013-052093 TRANSIENT THERMAL IMPEDANCE Thermal Impedance (C/W) PI-1012-051793 8 Tj = 120C 100 Power Dissipation (W) 6 10 4 1 2 0 0 25 50 75 100 125 0.1 10 -4 10 -3 10 -2 10 -1 1 10 100 1000 Case Temperature (C) Time (s) S16A DIM A B C E F J L M N inches .398-.413 .050 BSC .014-.018 .093-.104 .004-.012 .394-.418 .009-.012 .020-.040 .291-.299 mm 16 9 Plastic SO-16 (W) 10.10-10.50 1.27 BSC 0.36-0.46 2.35-2.65 0.10-0.30 10.01-10.62 0.23-0.32 0.51-1.02 7.40-7.60 1 (3) N Notes: 1. Package dimensions conform to JEDEC specification MS-013-AA for standard small outline (SO) package, 16 leads, 7.50 mm (.300 inch) body width (issue A, June 1985). 2. Controlling dimensions are in mm. 3. Dimensions are for the molded body and do not include mold flash or protrusions. Mold flash or protrusions shall not exceed .15 mm (.006 inch) on any side. 4. Pin 1 side identified by chamfer on top edge of the package body or indent on Pin 1 end. (3) A 8 J E L C B F M 0-8 TYP. PI-1846-050196 12 D 1/96 SMP402 NOTES D 1/96 13 SMP402 NOTES 14 D 1/96 SMP402 NOTES D 1/96 15 SMP402 Power Integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. Power Integrations does not assume any liability arising from the use of any device or circuit described herein, nor does it convey any license under its patent rights or the rights of others. PI Logo and TOPSwitch are registered trademarks of Power Integrations, Inc. (c)Copyright 1994, Power Integrations, Inc. 477 N. Mathilda Avenue, Sunnyvale, CA 94086 WORLD HEADQUARTERS Power Integrations, Inc. 477 N. Mathilda Avenue Sunnyvale, CA 94086 USA Main: 408*523*9200 Customer Service: Phone: 408*523*9265 Fax: 408*523*9365 JAPAN Power Integrations, K.K. Keihin-Tatemono 1st Bldg. 12-20 Shin-Yokohama 2-Chome, Kohoku-ku, Yokohama-shi, Kanagawa 222 Japan Phone: 81*(0)*45*471*1021 Fax: 81*(0)*45*471*3717 AMERICAS For Your Nearest Sales/Rep Office Please Contact Customer Service Phone: 408*523*9265 Fax: 408*523*9365 EUROPE & AFRICA Power Integrations (Europe) Ltd. Mountbatten House Fairacres Windsor SL4 4LE United Kingdom Phone: 44*(0)*1753*622*208 Fax: 44*(0)*1753*622*209 ASIA & OCEANIA For Your Nearest Sales/Rep Office Please Contact Customer Service Phone: 408*523*9265 Fax: 408*523*9365 APPLICATIONS HOTLINE World Wide 408*523*9260 APPLICATIONS FAX Americas 408*523*9361 Europe/Africa 44*(0)*1753*622*209 Japan 81*(0)*45*471*3717 Asia/Oceania 408*523*9364 16 D 1/96 |
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