XC9510 Series ETR1007_001 Synchronous Step-Down DC/DC Converter with Built-In LDO Regulator In Series Plus Voltage Detector ■GENERAL DESCRIPTION The XC9510 series consists of a step-down DC/DC converter and a high-speed LDO regulator connected in series with the DC/DC converter's output. A voltage detector is also built-in. A highly efficient, low noise output is possible since the regulator is stepped-down further from the DC/DC output. The DC/DC converter block incorporates a P-channel driver transistor and a synchronous N-channel switching transistor. With an external coil, diode and two capacitors, the XC9510 can deliver output currents up to 800mA at efficiencies over 90%. The XC9510 is designed for use with small ceramic capacitors. A choice of three switching frequencies are available, 300 kHz, 600 kHz, and 1.2 MHz. Output voltage settings for the DC/DC is set-up internally in 100mV steps within the range of 1.6V to 4.0V(±2.0%) and for the VR are set-up internally within the range of 0.9V to 4.0V (±2.0%). For the VD, the range is of 0.9V to 5.0V (±2.0%). The soft start time of the series is internally set to 5ms. With the built-in U.V.L.O. (Under Voltage Lock Out) function, the internal P-channel driver transistor is forced OFF when input voltage becomes 1.4 V or lower. The operational states of the DC/DC and the regulator blocks can be changed by inputting three kinds of voltage level via the CE/MODE pin. The functions of the MODE pin can be selected via the external control pin to switch the DC/DC control mode and the disable pin to shut down the regulator block. ■APPLICATIONS ●CD-R / RW, DVD ●HDD ●PDAs, portable communication modem ●Cellular phones ●Palmtop computers ●Cameras, video recorders ■FEATURES DC/DC Converter with Built-in LDO and VD Function Input Voltage Range : 2.4V ~ 6.0V Low ESR Capacitor : Ceramic capacitor compatible VD Function : Three Sensing Options for Either VDD, DCOUT or VROUT N-ch open drain output Package : SOP-8 <DC/DC Converter Block> Output Voltage Range : 1.6V ~ 4.0V (Accuracy ±2%) Output Current : 800mA, Controls : PWM or PWM/PFM Selectable Oscillation Frequency : 300kHz, 600kHz, 1.2MHz <Regulator Block> Regulator Input : Serial Input from DC/DC output Output Voltage Range : 0.9V ~ 4.0V (Accuracy±2%) Current Limit : 600mA Dropout Voltage : 160mV @ IOUT=200mA (VOUT=2.8V) High Ripple Rejection : 60dB @1kHz (VOUT=2.8V) ■TYPICAL APPLICATION CIRCUIT ■TYPICAL PERFORMANCE CHARACTERISTICS 1/36 XC9510 Series ■PIN CONFIGURATION SOP-8 (TOP VIEW) ■PIN ASSIGNMENT PIN NUMBER PIN NAME FUNCTION 1 2 3 4 5 6 7 8 PGND CE/MODE VDD VDOUT AGND VROUT DCOUT LX Power Ground Chip Enable / MODE Switch Power Supply VD Output Analog Ground VR Output DC/DC Output Switch ■PRODUCT CLASSIFICATION ●Ordering Information XC9510①②③④⑤⑥ DESIGNATOR The input for the voltage regulator block comes from the DC/DC. DESCRIPTION SYMBOL Control Methods And The VD Sense Pin Setting Voltage & Specifications ① ②③ ④ DC/DC Oscillation Frequency ⑤ Package ⑥ Device Orientation As chart below Internal standard 3 6 C S R L DESCRIPTION :: Setting voltage and specifications of each DC/DC, VR, and VD Based on the internal standard) : 300kHz : 600kHz : 1.2MHz : SOP-8 : Embossed Tape, standard feed : Embossed Tape, reverse feed ●Control Methods, CE/MODE Pin, VDSENSE Pin SERIES TYPE XC9510 A B C D E F H K L 2/36 DC/DC CONTROL METHODS PWM Control PWM, PFM/PWM Manual Switch CE=”VCEH” LEVEL CE=”VCEM” LEVEL CE=”VCEL” LEVEL VD SENSE PIN - - DC/DC: OFF VR: OFF VD: ON DC/DC: ON VR: OFF VD: ON DC/DC: ON VR: ON VD: ON DC/DC: OFF VR: OFF VD: ON PFM / PWM Automatic Switch PWM Control DC/DC: OFF VR: OFF VD: ON VDD DCOUT VROUT VDD DCOUT VROUT VDD DCOUT VROUT XC9510 Series ■BLOCK DIAGRAM * Diodes shown in the above circuit are protective diodes. ■ABSOLUTE MAXIMUM RATINGS Ta = 25℃ PARAMETER SYMBOL RATINGS UNIT VDD Pin Voltage VDD - 0.3 ~ 6.5 V DCOUT Pin Voltage DCOUT - 0.3 ~ VDD + 0.3 V VROUT Pin Voltage VROUT - 0.3 ~ VDD + 0.3 V VROUT Pin Current IROUT 800 mA VDOUT Pin Voltage VDOUT - 0.3 ~ VDD + 0.3 V VDOUT Pin Current IVD 50 mA Lx Pin Voltage Lx - 0.3 ~ VDD + 0.3 V Lx Pin Current ILx ±1300 mA CE/MODE Pin Voltage CE/MODE - 0.3 ~ VDD + 0.3 V Pd 650* mW Operating Temperature Range Topr - 40 ~ + 85 ℃ Storage Temperature Range Tstg - 55 ~ + 125 ℃ Power Dissipation SOP-8 (*) When PC board mounted. 3/36 XC9510 Series ■ELECTRICAL CHARACTERISTICS XC9510xxxCSx ●Common Characteristics Topr=25℃ PARAMETER SYMBOL Supply Current 1 IDD1 VIN=CE=DCOUT=5.0V - 250 310 μA 1 Supply Current 2 IDD2 VIN=CE=5.0V, DCOUT=0V - 300 360 μA 1 Stand-by Current (*1) ISTB VIN=6.5V, CE=0V - 3.0 7.0 μA 1 Input Voltage Range VIN 2.4 - 6.0 V - VCEH VDD-0.3 - VDD V 2 VCEH VDD-0.3 - VDD V 3 CE ‘M’ Level Voltage VCEM 0.6 - VDD-1.2 V 3 CE ‘H’ Level Voltage *XC9510D/E/F CE ‘H’ Level Voltage *XC9510H/K/L CONDITIONS MIN. TYP. MAX. UNITS CIRCUIT CE ‘L’ Level Voltage VCEL VSS - 0.25 V 3 CE ‘H’ Level Current ICEH - 0.1 - 0.1 μA 1 CE ‘L’ Level Current ICEL - 0.1 - 0.1 μA 1 MIN. TYP. MAX. UNITS CIRCUIT ●DC/DC Converter (2.2V product) Topr=25℃ PARAMETER SYMBOL Supply Current 1 *XC9510D/E/F IDD_DC1 VIN=CE=DCOUT=5.0V - 200 280 μA 1 Supply Current 2 *XC9510D/E/F IDD_DC2 VIN=CE=5.0V, DCOUT=0V - 250 330 μA 1 IDD_PFM1 VIN=CE=DCOUT=5.0V - 250 310 μA 1 IDD_PFM2 VIN=CE=5.0V, DCOUT=0V - 300 360 μA 1 2.156 2.200 2.244 V 3 1.02 1.20 1.38 MHz 3 DCOUT=0V 100 - - % 4 DCOUT=VIN - - 0 % 4 21 30 38 % 3 1.00 1.40 1.78 V 3 - 0.5 0.9 Ω 5 - 0.5 0.9 Ω 3 - 0.05 1.00 μA 11 PFM Supply Current 1 *XC9510H/K/L PFM Supply Current 2 *XC9510H/K/L Output Voltage DCOUT(E) Oscillation Frequency FOSC Maximum Duty Ratio MAXDUTY Minimum Duty Ratio MINDUTY PFM Duty Ratio PFMDUTY U.V.L.O. Voltage (*2) VUVLO LX SW ‘High’ ON Resistance (*3) RLXH LX SW ‘Low’ ON Resistance RLXL LX SW ‘High’ Leak Current (*12) IleakH CONDITIONS Connected to the external components, IDOUT=30mA Connected to the external components, IDOUT=10mA Connected to the external components, No load Connected to the external components DCOUT=0V, LX=VIN-0.05V Connected to the external components, VIN=5.0V VIN=LX=6.0V, CE=0V LX SW ‘Low’ Leak Current (*12) IleakL VIN=6.0V, LX=CE=0V Maximum Output Current Imax1 Connected to the external components Current Limit (*9) Ilim1 Efficiency (*4) EFFI Output Voltage Temperature Characteristics UDCOUT UTopr・DCOUT Soft-Start Time TSS Latch Time (*5, 10) Tlat 4/36 Connected to the external components, IDOUT=100mA IDOUT=30mA -40℃≦Topr≦85℃ Connected to the external components, CE=0VtVIN, IDOUT=1mA Connected to the external components, VIN=CE=5.0V, Short DCOUT by 1Ωresistor - 0.05 1.00 μA 11 800 - - mA 3 1.0 1.1 - A 6 - 90 - % 3 - +100 - 2 5 10 ms 3 - 8 25 ms 10 ppm/ ℃ 3 XC9510 Series ■ELECTRICAL CHARACTERISTICS (Continued) XC9510xxxCSx (Continued) ●Regulator (1.8V product) Topr=25℃ PARAMETER SYMBOL CONDITIONS MIN. TYP. MAX. 1.764 1.800 1.836 V 2 400 - - mA 2 1mA≦IROUT≦100mA - 15 50 mV 2 IROUT=30mA UNITS CIRCUIT Output Voltage VROUT(E) Maximum Output Current Imax2 Load Regulation U VROUT Dropout Voltage 1 (*6) Vdif 1 IROUT=100mA - 100 200 mV 2 Dropout Voltage 2 Vdif 2 IROUT=200mA - 200 400 mV 2 Line Regulation UVROUT UVIN・VROUT IROUT=30mA - 0.05 0.25 %/V 2 480 600 - mA 7 - 30 - mA 7 - 60 - dB 12 - +100 - VROUT(T)+1V≦VIN≦6V Current Limit Ilim2 VROUT=VROUT(E) x 0.9 Short-Circuit Current Ishort VROUT=VSS VIN={VOUT(T)+1.0} VDC+0.5Vp-pAC, Ripple Rejection Rate PSRR Output Voltage UVROUT UTopr・VROUT Temperature Characteristics IROUT=30mA, f=1kHz IROUT=30mA -40℃≦Topr≦85℃ ppm/ ℃ 2 ●Detector (2.7V product) PARAMETER SYMBOL Detect Voltage VDF(E) CONDITIONS CE=0V (*11) TYP. MAX. 2.700 2.754 UNITS CIRCUIT V 8 Hysteresis Range VHYS VHYS=[VDR(E) 2 5 8 % 8 VD Output Current IVD VDOUT=0.5V, CE=0V 1 - - mA 9 Output Voltage UVDF UTopr・VDF -40℃≦Topr≦85℃ - +100 - Temperature Characteristics - VDF(E)] / VDF(E) x 100 MIN. 2.646 ppm/ ℃ 8 Test conditions: Unless otherwise stated: DC/DC : VIN=3.6V [@ DCOUT:2.2V] VR: VIN = 2.8V (VIN=VROUT(T) + 1.0V) VD: VIN=5.0V Common conditions for all test items: CE=VIN, MODE=0V * VROUT(T) : Setting output voltage NOTE: *1 : Including VD supply current (VD operates when in stand-by mode.) *2 : Including hysteresis operating voltage range. *3 : ON resistance (Ω)= 0.05 (V) / ILX (A) *4 : EFFI = { ( Output Voltage x Output Current ) / ( Input Voltage x Input Current) } x 100 *5 : Time until it short-circuits DCOUT with GND through 1Ωof resistance from a state of operation and is set to DCOUT=0V from current limit pulse generating. *6 : Vdif = (VIN1 (*7) - VROUT1 (*8) ) *7 : VIN 1 = The input voltage when VROUT1 appears as input voltage is gradually decreased. *8 : VROUT1 = A voltage equal to 98% of the output voltage whenever an amply stabilized IOUT {VROUT(T) + 1.0V} is input. *9 : Current limit = When VIN is low, limit current may not be reached because of voltage falls caused by ON resistance or serial resistance of coils. *10: Integral latch circuit=latch time may become longer and latch operation may not work when VIN is 3.0V or more. *11: VDR(E) = VD release voltage *12: When temperature is high, a current of approximately 5.0μA (maximum) may leak. 5/36 XC9510 Series ■TEST CIRCUITS Circuit 1 Supply Current, Stand-by Current, CE Current PGND 1 CE/ MODE 2 3 A A VDD 4 VDOUT LX Circuit 2 Output Voltage (VR), Load Regulation, Dropout Voltage, Maximum Output Current, (MODE Voltage) 8 DCOUT : VIN or GND DCOUT CE/MODE : VIN or VIN-1.2V or GND 1 7 VROUT 6 5 AGND LX 8 2 CE/ MODE DCOUT 7 3 VDD VROUT 6 4 VDOUT AGND 5 PGND V V IROUT CIN : 4.7uF (ceramic) CIN : 1.0uF (ceramic) CL:4.7uF(ceramic, 10uF(ceramic, Circuit 3 Output Voltage (DC/DC) Oscillation Frequency, U.V.L.O. Voltage, Soft-start Time, CE Voltage, Maximum Output Current, Efficiency, (PFM Duty Cycle), (MODE Voltage) IROUT<300mA ) IROUT>3 0 0 mA ) Circuit 4 Minimum Duty Cycle, Maximum Duty Cycle Probe PGND 1 2 3 4 CE/ MODE VDD LX 8 DCOUT 7 L VROUT VDOUT Probe AGND CE : VIN LX 8 2 CE/ MODE DCOUT 7 6 3 VDD VROUT 6 5 4 VDOUT AGND 5 V IDOUT 200Ω V V CL : 10uF (ceramic) CIN : 4.7uF (ceramic) Fosc 300kHz 600kHz 1.2MHz Circuit 5 PGND 1 CIN : 1.0uF(ceramic) L 22uH(CDRH6D38, SUMIDA) 10uH(CDRH5D28, SUMIDA) 4.7uH(CDRH4D28C, SUMIDA) Lx ON Resistance Circuit 6 Current Limit 1 (DC/DC) Probe 1 CE : VIN PGND LX 8 1 A 6/36 LX 8 2 CE/ MODE DCOUT 7 6 3 VDD VROUT 6 5 4 VDOUT AGND 5 2 CE/ MODE DCOUT 7 3 VDD VROUT 4 VDOUT AGND CE : VIN V CIN : 1.0uF (ceramic) PGND CIN : 4.7uF (ceramic) A ILX XC9510 Series ■TEST CIRCUITS (Continued) Circuit 7 Current Limit 2 (VR), Short Circuit Current (VR) Circuit 8 Detect Voltage, Release Voltage (Hysteresis Range) VD_SENSE* (DCOUT or VROUT) LX 8 2 CE/ MODE PGND DCOUT 7 3 VDD VROUT 6 4 VDOUT AGND 5 1 CE/MODE : VSS 200k Ω V V CIN: 1uF * For the measurement of the VDD_Sense products, the input voltage was controlled. Circuit 9 VD Output Current Circuit 10 Latch Time L VD_SENSE* (DCOUT or VROUT) PGND 1 CE : VSS A LX 8 1 PGND 8 2 CE/ MODE DCOUT 7 2 CE/ MODE DCOUT 7 3 VDD VROUT 6 3 VDD VROUT 6 4 VDOUT AGND 5 4 VDOUT AGND 5 V V V 1Ω CL : 10uF (ceramic) CIN : 4.7uF (ceramic) CIN : 1uF (ceramic) * For the measurement of the VDD_Sense products, the input voltage was controlled. Circuit 11 LX Off-Leak Circuit 12 1 CE/MODE : VSS 2 3 A V Fosc 300kHz 600kHz 1.2MHz 4 PGND LX CE/ MODE DCOUT VDD VROUT VDOUT AGND A 8 Ripple Rejection Rate CE/MODE : VIN or VIN-1.2V or GND LX 8 2 CE/ MODE DCOUT 7 3 VDD VROUT 6 4 VDOUT AGND 5 1 7 6 5 L 22uH(CDRH6D38, SUMIDA) 10uH(CDRH5D28, SUMIDA) 4.7uH(CDRH4D28C, SUMIDA) A ~ PGND V V IROUT CIN : 1.0uF (ceramic) CIN : 4.7uF (ceramic) CL:4.7uF(ceramic, 10uF(ceramic, IROUT<300mA ) IROUT>3 0 0mA ) 7/36 XC9510 Series ■TYPICAL APPLICATION CIRCUIT FOSC L 1.2MHz 4.7μH (CDRH4D28C, SUMIDA) 600kHz 10μH (CDRH5D28, SUMIDA) 300kHz 22μH (CDRH6D28, SUMIDA) SOP-8 (TOP VIEW) CIN CL1 4.7μF(ceramic, TAIYO YUDEN) 10μF(ceramic, TAIYO YUDEN) CL2 *2 IROUT<300mA 4.7μF (ceramic, TAIYO YUDEN) IROUT>300mA 10μF (ceramic, TAIYO YUDEN) *1 The DC/DC converter of the XC9510 series automatically switches between synchronous / non-synchronous. The Schottky diode is not normally needed. However, in cases where high efficiency is required when using the DC/DC converter during in the light load while in non-synchronous operation, please connect a Schottky diode externally. *2 Please be noted that the recommend value above of the CL2 may be changed depending on the input voltage value and setting voltage value. ■OPERATIONAL EXPLANATION The XC9510 series consists of a synchronous step-down DC/DC converter, a high speed LDO voltage regulator, and a voltage detector. Since the LDO voltage regulator is stepped-down from the DC/DC’s output,high efficiency and low noise is possible even at lower output voltages. ●DC/DC Converter The series consists of a reference voltage source, ramp wave circuit, error amplifier, PWM comparator, phase compensation circuit, output voltage adjustment resistors, driver transistor, synchronous switch, current limiter circuit, U.V.L.O. circuit and others. The series ICs compare, using the error amplifier, the voltage of the internal voltage reference source with the feedback voltage from the VOUT pin through split resistors. Phase compensation is performed on the resulting error amplifier output, to input a signal to the PWM comparator to determine the turn-on time during PWM operation. The PWM comparator compares, in terms of voltage level, the signal from the error amplifier with the ramp wave from the ramp wave circuit, and delivers the resulting output to the buffer driver circuit to cause the Lx pin to output a switching duty cycle. This process is continuously performed to ensure stable output voltage. The current feedback circuit monitors the P-channel MOS driver transistor current for each switching operation, and modulates the error amplifier output signal to provide multiple feedback signals. This enables a stable feedback loop even when a low ESR capacitor, such as a ceramic capacitor, is used, ensuring stable output voltage. <Reference Voltage Source> The reference voltage source provides the reference voltage to ensure stable output voltage of the DC/DC converter. <Ramp Wave Circuit> The ramp wave circuit determines switching frequency. The frequency is fixed internally and can be selected from 300kHz, 600 kHz and 1.2 MHz. Clock pulses generated in this circuit are used to produce ramp waveforms needed for PWM operation, and to synchronize all the internal circuits. <Error Amplifier> The error amplifier is designed to monitor output voltage. The amplifier compares the reference voltage with the feedback voltage divided by the internal split resistors. When a voltage lower than the reference voltage is fed back, the output voltage of the error amplifier increases. The gain and frequency characteristics of the error amplifier output are fixed internally to deliver an optimized signal to the mixer. 8/36 XC9510 Series ■OPERATIONAL EXPLANATION (Continued) <PWM/PFM> The XC9510A to F series are PWM control, while the XC9510H to L series can be automatically switched between PWM control and PWM/PFM control. The PWM of the XC9510A to F series are controlled on a specified frequency from light loads through the heavy loads. Since the frequency is specified, the composition of a noise filter etc. becomes easy. However, the efficiency at the time of the light load may become low. The XC9510H to L series can switch in any timing between PWM control and PWM/PFM automatic switching control. The series cannot control only PFM mode. If needed, the operation can be set on a specified frequency; therefore, the control of the noise etc. is possible and the high efficiency at the time of the light load during PFM control mode is possible. With the automatic PWM/PFM switching control function, the series ICs are automatically switched from PWM control to PFM control mode under light load conditions. If during light load conditions the coil current becomes discontinuous and on-time rate falls lower than 30%, the PFM circuit operates to output a pulse with 30% of a fixed on-time rate from the Lx pin. During PFM operation with this fixed on-time rate, pulses are generated at different frequencies according to conditions of the moment. This causes a reduction in the number of switching operations per unit of time, resulting in efficiency improvement under light load conditions. However, since pulse output frequency is not constant, consideration should be given if a noise filter or the like is needed. Necessary conditions for switching to PFM operation depend on input voltage, load current, coil value and other factors. <Synchronous / Non-synchronous> The XC9510 series automatically switches between synchronous / non-synchronous according to the state of the DC/DC converter. Highly efficient operations are achievable using the synchronous mode while the coil current is in a continuous state. The series enters non-synchronous operation when the built-in N-ch switching transistor for synchronous operation is shutdown which happens when the load current becomes low and the operation changes to a discontinuous state. The IC can operate without an external schottky diode because the parasitic diode in the N-ch switching transistor provides the circuit's step-down operation. However, since Vf of the parasitic diode is a high 0.6V, the efficiency level during non-synchronous operation shows a slight decrease. Please use an external schottky diode if high efficiency is required during light load current. ●Continuous Mode: Synchronous ●Discontinuous Mode: Non-Synchronous 9/36 XC9510 Series ■OPERATIONAL EXPLANATION (Continued) <Current Limit> The current limiter circuit of the XC9510 series monitors the current flowing through the P-channel MOS driver transistor connected to the Lx pin, and features a combination of the constant-current type current limit mode and the operation suspension mode. ① When the driver current is greater than a specific level, the constant-current type current limit function operates to turn off the pulses from the Lx pin at any given timing. ② When the driver transistor is turned off, the limiter circuit is then released from the current limit detection state. ③ At the next pulse, the driver transistor is turned on. However, the transistor is immediately turned off in the case of an over current state. ④ When the over current state is eliminated, the IC resumes its normal operation. The IC waits for the over current state to end by repeating the steps ① through ③ . If an over current state continues for 8msec* and the above three steps are repeatedly performed, the IC performs the function of latching the OFF state of the driver transistor, and goes into operation suspension mode. Once the IC is in suspension mode, operations can be resumed by either turning the IC off via the CE/MODE pin, or by restoring power to the VIN pin. The suspension mode does not mean a complete shutdown, but a state in which pulse output is suspended; therefore, the internal circuitry remains in operation. The constant-current type current limit of the XC9510 series can be set at 1.1A. <U.V.L.O. Circuit> When the VIN pin voltage becomes 1.4 V or lower, the P-channel output driver transistor is forced OFF to prevent false pulse output caused by unstable operation of the internal circuitry. When the VIN pin voltage becomes 1.8 V or higher, switching operation takes place. By releasing the U.V.L.O. function, the IC performs the soft start function to initiate output startup operation. The soft start function operates even when the VIN pin voltage falls momentarily below the U.V.L.O. operating voltage. The U.V.L.O. circuit does not cause a complete shutdown of the IC, but causes pulse output to be suspended; therefore, the internal circuitry remains in operation. ●High Speed LDO Voltage Regulator The voltage regulator block of the XC9510 series consists of a reference voltage source, error amplifier, and current limiter circuit.The voltage divided by split resistors is compared with the internal reference voltage by the error amplifier. The P-channel MOSFET, which is connected to the VROUT pin, is then driven by the subsequent output signal. The output voltage at the VROUT pin is controlled and stabilized by a system of negative feedback. A stable output voltage is achievable even if used with low ESR capacitors as a phase compensation circuit is built-in. <Reference Voltage Source> The reference voltage source provides the reference voltage to ensure stable output voltage of the regulator. <Error Amplifier> The error amplifier compares the reference voltage with the signal from VROUT, and the amplifier controls the output of the P-ch driver transistor. <Current Limit Circuit> The voltage regulator block includes a combination of a constant current limiter circuit and a foldback circuit. When the load current reaches the current limit level, the current limiter circuit operates and the output voltage of the voltage regulator block drops. As a result of this drop in output voltage, the foldback circuit operates, output voltage drops further and the load current decreases. When the VROUT and GND pin are shorted, the load current of about 30mA flows. 10/36 XC9510 Series ■OPERATIONAL EXPLANATION (Continued) ●Voltage Detector The detector block of the XC9510 series detects output voltage from the VDOUT pin while sensing either VDD, DCOUT, or VROUT internally. (N-channel Open Drain Type) < CE / MODE Pin Function> The operation of the XC9510 series' DC/DC converter block and voltage regulator block will enter into the shut down mode when a low level signal is input to the CE/MODE pin. During the shut down mode, the current consumption occurs only in the detector and is 3.0μA (TYP.), with a state of high impedance at the Lx pin and DCOUT pin. The IC starts its operation by inputting a high level signal or a middle level signal to the CE/MODE pin. The input to the CE/MODE pin is a CMOS input and the sink current is 0μA (TYP.). The operation of the XC9510D to F series' voltage detector block will enter into stand-by mode when a high level signal is input to the CE/MODE pin. The voltage regulator block will operate when a middle level signal is input. But when a low level signal is input, the voltage regulator block will enter into stand-by mode. With the XC9510H to L series control can be PWM control when the CE/MODE pin is 'M' level and PWM/PFM automatic switching control when the CE/MODE pin is 'H' level. ■NOTES ON USE ●Application Information 1. The XC9510 series is designed for use with ceramic output capacitors. If, however, the potential difference between dropout voltage or output current is too large, a ceramic capacitor may fail to absorb the resulting high switching energy and oscillation could occur on the output. If the input-output potential difference is large, connect an electrolytic capacitor in parallel to compensate for insufficient capacitance. 2. Spike noise and ripple voltage arise in a switching regulator as with a DC/DC converter. These are greatly influenced by external component selection, such as the coil inductance, capacitance values, and board layout of external components. Once the design has been completed, verification with actual components should be done. 3. When the difference between VIN and VOUT is large in PWM control, very narrow pulses will be outputted, and there is the possibility that some cycles may be skipped completely. 4. When the difference between VIN and VOUT is small, and the load current is heavy, very wide pulses will be outputted and there is the possibility that some cycles may be skipped completely: in this case, the Lx pin may not go low at all. ●DC/DC Waveform (3.3V, 1.2MHz) < External Components> L:4.7μH(CDRH4D28C,SUMIDA) CIN:4.7μF(ceramic) CL:10μF(ceramic) < External Components> L:4.7μH(CDRH4D28C,SUMIDA) CIN:4.7μF(ceramic) CL:10μF(ceramic) 11/36 XC9510 Series ■NOTES ON USE (Continued) ●Application Information (Continued) 5. The IC's DC/DC converter operates in synchronous mode when the coil current is in a continuous state and non-synchronous mode when the coil current is in a discontinuous state. In order to maintain the load current value when synchronous switches to non-synchronous and vise versa, a ripple voltage may increase because of the repetition of switching between synchronous and non-synchronous. When this state continues, the increase in the ripple voltage stops. To reduce the ripple voltage, please increase the load capacitance value or use a schottky diode externally. When the current used becomes close to the value of the load current when synchronous switches to non- synchronous and vise versa, the switching current value can be changed by changing the coil inductance value. In case changes to coil inductance are to values other than the recommended coil inductance values, verification with actual components should be done. Ics = (VIN - DCOUT) x OnDuty / (L x Fosc) Ics: Switching current from synchronous rectification to non-synchronous rectification . OnDuty: OnDuty ratio of P-ch driver transistor ( =.step down ratio : DCOUT / VIN) L: Coil inductance value Fosc: Oscillation frequency IDOUT: The DC/DC load current (the sum of the DC/DC's and the regulator's load if the regulator has load.) 6. When the XC9510H to L series operates in PWM/PFM automatic switching control mode, the reverse current may become quite high around the load current value when synchronous switches to non-synchronous and vise versa (also refer to no. 5 above). Under this condition, switching synchronous rectification and non-synchronous rectification may be repeated because of the reverse current, and the ripple voltage may be increased to 100mV or more. The reverse current is the current that flows in the PGND direction through the N-ch driver transistor from the coil. The conditions which cause this operation are as follows. PFM Duty < Step down ratio = DCOUT / VIN x 100 (%) PFM Duty: 30% (TYP.) Please switch to PWM control via the MODE function in cases where the load current value of the DC/DC converter is close to synchronous. ●DC/DC Waveform (1.8V, 600kHz) @ VIN=6.0V < External Components> L:10μH(CDRH5D28C,SUMIDA) CIN:4.7μF(ceramic) CL:10μF(ceramic) Step down ratio : 1.8V / 6.0V = 30%<PFM Duty 31%> 12/36 XC9510 Series ■NOTES ON USE (Continued) ●Application Information (Continued) 7. With the DC/DC converter of the IC, the peak current of the coil is controlled by the current limit circuit. Since the peak current increases when dropout voltage or load current is high, current limit starts operating, and this can lead to instability. When peak current becomes high, please adjust the coil inductance value and fully check the circuit operation. In addition, please calculate the peak current according to the following formula: Peak current: Ipk = (VIN - DCOUT) x OnDuty / (2 x L x Fosc) + IDOUT 8. When the peak current, which exceeds limit current flows within the specified time, the built-in driver transistor is turned off (the integral latch circuit). During the time until it detects limit current and before the built-in transistor can be turned off, the current for limit current flows; therefore, care must be taken when selecting the rating for the coil or the Schottky diode. 9. When VIN is low, limit current may not be reached because of voltage falls caused by ON resistance or serial resistance of the coil. 10. In the integral latch circuit, latch time may become longer and latch operation may not work when VIN is 3.0V or more. 11. Use of the IC at voltages below the recommended voltage range may lead to instability. 12. This IC and the external components should be used within the stated absolute maximum ratings in order to prevent damage to the device. 13. Since the DC/DC converter and the regulator of the XC9510 series are connected in series, the sum of the output current (IDOUT) of the DC/DC and the output current (IROUT) of the VR makes the current flows inside the DC/DC converter. Please be careful of the power dissipation when in use. Please calculate power dissipation by using the following formula. Pd=PdDC/DC + PdVR 2 DC/DC power dissipation (when in synchronous operation) : PdDC/DC = IDOUT x RON VR power dissipation: PdVR=(DCOUT – VROUT) x IROUT RON: ON resistance of the built-in driver transistor to the DC/DC (= 0.5Ω<TYP.>) RON=Rpon x P-chOnDuty / 100 + Rnon x (1 – P-chOnDuty / 100) 14. The voltage detector circuit built-in the XC9510 series internally monitor the VDD pin voltage, the DC/DC output pin voltage and VR output pin voltage. For the XC9510B/C/E/F/K/L series, which voltage detector circuit monitors the DC/DC output pin voltage and the VR output pin voltage, please determine the detect voltage value (VDF) by the following equation. VDF≦(Setting voltage on both the DCOUT voltage and the VROUT voltage)×85%* * An assumed value of tolerance among the DCOUT voltage, the VROUT voltage, and the VD release voltage (The VD detect voltage and hysteresis range). 13/36 XC9510 Series ■NOTES ON USE (Continued) ●Instructions on Pattern Layout 1. In order to stabilize VIN's voltage level, we recommend that a by-pass capacitor (CIN) be connected as close as possible to the VDD & AGND pins. This IC is the composite IC of the DC/DC converter and regulator. Fluctuation of the VIN's voltage level causes mutual interference. 2. Please mount each external component as close to the IC as possible. 3. Wire external components as close to the IC as possible and use thick, short connecting traces to reduce the circuit impedance. 4. Make sure that the PCB GND traces are as thick as possible, as variations in ground potential caused by high ground currents at the time of switching may result in instability of the DC/DC converter and have adverse influence on the regulator output. 5. If using a Schottky diode, please connect the anode side to the AGND pin through CIN. caused by the noise may occur depending on the arrangement of the Schottky diode. <SOP-8 Reference pattern layout> 14/36 Characteristic degradation XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (A) DC/DC CONVERTER (1) Efficiency vs. Output Current 15/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (2) Output Voltage vs. Output Current 16/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (3) Output Voltage vs. Ripple Voltage 17/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (4) Output Voltage vs. Ambient Temperature (5) Soft Start Time vs. Ambient Temperature 18/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (6) DC/DC Supply Current vs. Ambient Temperature(VR:Shutdown)* 19/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (7) LX P-ch/N-ch On Resistance vs. Input Voltage (8) Oscillation Frequency vs. Ambient Temperature 20/36 (9) U.V.L.O. Voltage vs. Ambient Temperature XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (10-2) DC/DC Load Transient Response (*DCOUT:3.3V FOSC:1.2MHz) (a) PWM Control (b) PWM/PFM Automatic Switching Control* (*XC9510H/K/L Series Only) 21/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (10-3) DC/DC Load Transient Response (*DCOUT:1.8V FOSC:600kHz) (a) PWM Control (b) PWM/PFM Automatic Switching Control* (*XC9510H/K/L Series Only) 22/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (A) DC/DC CONVERTER (Continued) (10-4) DC/DC Load Transient Response (*DCOUT:3.3V FOSC:600kHz) (a) PWM control (b) PWM/PFM Automatic Switching Control* (*XC9510H/K/L Series Only) 23/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (1) Output Voltage VS. Input Voltage 24/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (2) Output Voltage VS. Output Current (Current Limit) 25/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (3) Dropout Voltage VS. Output Current 26/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (4) Output Voltage VS. Output Current 27/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (5) Output Voltage VS. Ambient Temperature 28/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (6) Ripple Rejection Ratio VS. Ripple Frequency 29/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (B) VOLTAGE REGULATOR (Continued) (7) VR LOAD TRANSIENT RESPONSE 30/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (C) VOLTAGE DETECTOR (1) Output Current VS. Input Voltage (2) Detect Voltage VS. Input Voltage 31/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (C) VOLTAGE DETECTOR (Continued) (3) Detect Voltage,Release Voltage VS. Ambient Temperature 32/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (D) COMMON (1) Supply Current VS. Ambient Temperature (DC/DC & VR & VD) (2) Shutdown Current VS. Input Voltage (3) Shutdown Current VS. Ambient Temperature 33/36 XC9510 Series ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (D) COMMON (Continued) (4) CE/MODE Pin Threshold Voltage* Ambient Temperature:Ta(℃) * Control Methods, CE/MODE Pin, VDSENSE Pin SERIES TYPE XC9510 A B C D E F H K L DC/DC CONTROL METHODS PWM Control PWM, PFM/PWM Manual Switch CE=”VCEH” LEVEL CE=”VCEM” LEVEL - - DC/DC: ON VR: OFF VD: ON DC/DC: ON VR: ON VD: ON PFM / PWM Automatic Switch PWM Control CE=”VCEL” LEVEL VD SENSE PIN DC/DC: OFF VR: OFF VD: ON DC/DC: OFF VR: OFF VD: ON DC/DC: OFF VR: OFF VD: ON VDD DCOUT VROUT VDD DCOUT VROUT VDD DCOUT VROUT ■PACKAGING INFORMATION ●SOP-8 SOP-8 (TOP VIEW) 34/36 XC9510 Series ■MARKING RULE ●SOP-8 ①②Represents product series MARK ① 1 PRODUCT SERIES ② 0 XC9510xxxxSx ③Represents DC/DC control methods, CE/MODE pins and VD sense pin MARK DC/DC CONTROL CE/MODE PIN (H level) CE/MODE PIN (M level) - - CE/MODE PIN (L level) A B C PWM Control D VR:OFF E VR:ON F H K L PWM,PFM/PWM PFM/PWM Manual Switch Auto Switch VD SENSE PRODUCT SERIES VDD XC9510A***S* DCOUT XC9510B***S* VROUT XC9510C***S* DC/DC:OFF VDD XC9510D***S* VR:OFF DCOUT XC9510E***S* VD:ON VROUT XC9510F***S* VDD XC9510H***S* DCOUT XC9510K***S* VROUT XC9510L***S* PWM Control ④⑤Represents detect voltage DC/DC,VR and VD ex) MARK ④ 1 ⑤ 3 DC/DC VR VD PRODUCT SERIES 3.3V 1.8V 4.0V XC9510*13*S* ⑥Represents oscillation frequency. MARK 3 6 C OSCILLATION FREQUENCY 300kHz 600kHz PRODUCT SERIES XC9510***3A* XC9510***6A* 1.2MHz XC9510***CA* ⑦Represents last digit of production year. ex) MARK 3 4 PRODUCTION YEAR 2003 2004 ⑧⑨Represents production lot number 0 to 9,A to Z reverse character 0 to 9, A to Z repeated (G,I,J,O,Q,W excepted) Note: No character inversion used 35/36 XC9510 Series 1. The products and product specifications contained herein are subject to change without notice to improve performance characteristics. Consult us, or our representatives before use, to confirm that the information in this catalog is up to date. 2. We assume no responsibility for any infringement of patents, patent rights, or other rights arising from the use of any information and circuitry in this catalog. 3. Please ensure suitable shipping controls (including fail-safe designs and aging protection) are in force for equipment employing products listed in this catalog. 4. The products in this catalog are not developed, designed, or approved for use with such equipment whose failure of malfunction can be reasonably expected to directly endanger the life of, or cause significant injury to, the user. (e.g. Atomic energy; aerospace; transport; combustion and associated safety equipment thereof.) 5. Please use the products listed in this catalog within the specified ranges. Should you wish to use the products under conditions exceeding the specifications, please consult us or our representatives. 6. We assume no responsibility for damage or loss due to abnormal use. 7. All rights reserved. No part of this catalog may be copied or reproduced without the prior permission of Torex Semiconductor Ltd. 36/36