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| x P Channel Power MOSFET Built-in x Maximum Output Current: 500mA x Output Voltage Range: 1.5~6.0V x Oscillator Frequency: 300kHz x Maximum Duty Ratio: 100% x High Efficiency: 95% x SOP-8 Package s General Description The XC6376/77 series are step-down DC/DC converters with built-in P channel power MOSFETs. A highly efficient DC/DC converter with output currents of 500mA can be realised using only four peripherals - a coil, a diode and 2 capacitors. Output voltage can be internally set-up in 0.1V increments (2.5%) between 1.5V and 6.0V (VOUT type). Alternatively, output voltage can be set-up at will using a 1.0V internal reference voltage source and peripherals (FB type). It is possible to reduce the size of the peripherals used since the switching frequency is 300kHz. The PWM//PFM switchable XC6377 operates in PFM mode during light loads and is highly efficient from light loads to large output currents. Required values for soft start time can be regulated via the external capacitor and the stand-by function reduces supply current to less than 2.5A. U.V.L.O and protection are built-in. s Applications q Electronic Information Organizers q Palmtops q Cellular and portable phones q Portable Audio Systems q Various Multi-function Power Supplies s Features Input voltage range: 1.8V~10V Output voltage range: 1.5V~6.0V programmable in 0.1V steps (2.5%) Oscillator frequency: 300kHz (15%) Custom products for 180, 500kHz Max. output current: 500mA (min.)VIN=3.6V, VOUT=3.0V High Efficiency: 95% (typ.) Stand-by capability: ISTB=2.5A (max.) Soft-start time set-up externally type U.V.L.O, Pch boost, VOUT reset functions available Internally set-up output voltage type (VOUT) Externally set-up output voltage type (FB) Pchannel Power MOSFET built-in Package: SOP-8 e s Pin Configuration VIN EXT/2 p_BST CE 1 2 3 4 8 7 6 5 LX EXT/1 s Pin Assignment PIN NUMBER 1 2 GND PIN NAME VIN EXT/2 P_BST CE VOUT (FB) GND EXT/1 LX FUNCTION Power supply input External drive pin 2 ("L" when Pch MOSFET ON) Pch gate boost Chip enable Soft-start capacitor connection Output voltage monitor (FB=externally set-up type) Ground External drive pin 1 ("L" when Pch MOSFET ON) Pch power MOSFET switch 3 VOUT SOP-8 (TOP VIEW) 4 5 6 7 8 s Selection Guide START Output Voltage Internally set-up (VOUT) Reset Function - Yes Protect Circuit - Yes XC6376E, XC6377E XC6376F, XC6377F e Protect Circuit - No Reset Function - No Protect Circuit - Yes Protect Circuit - No XC6376A, XC6377A XC6376C, XC6377C Output Voltage Externally set-up (FB) Protect Circuit - Yes Protect Circuit - No XC6376B, XC6377B XC6376D, XC6377D s Ordering Information XC6376 XC6376 Series SYMBOL A B C D E F PWM Control VOUT/FB VOUT FB VOUT FB VOUT VOUT VOUT RESET FUNCTION NO NO YES YES =0) INTEGRAL CIRCUIT PROTECTION YES YES NO NO YES NO Output voltage e.g. 3.0V output : ( =3, FB products (B,D types) : ( =1, =0) 3 5 2 S R L Oscillator frequency 300kHz Oscillator frequency 500kHz Oscillator frequency 180kHz Package SOP-8 Embossed Tape : standard loading : reverse loading XC6377 XC6377 Series PWM/PFM switching control (same as XC6376 series) s Block Diagram XC6376, XC6377 Series A,C types (VOUT) VIN VOUT Protection Pch POWER MOS FET Phase Compensation LX EXT/1 + CE CE, Vref with Soft Start Error Amp. + - PWM Comparator Buffer, Driver e EXT/2 P_BST PWM/PFM Controller Ramp Wave Generator, OSC GND XC6376, XC6377 Series B,D types (FB) VIN VOUT Protection Pch POWER MOS FET Phase Compensation LX EXT/1 + CE CE, Vref with Soft Start Error Amp. + - PWM Comparator Buffer, Driver EXT/2 P_BST PWM/PFM Controller Ramp Wave Generator, OSC GND XC6376, XC6377 Series E,F types (VOUT, VOUT rest function) VIN VOUT Protection Pch POWER MOS FET Phase Compensation LX EXT/1 e + CE CE, Vref with Soft Start Error Amp. + - PWM Comparator Buffer, Driver EXT/2 P_BST PWM/PFM Controller Ramp Wave Generator, OSC GND s Absolute Maximum Ratings PARAMETER VIN Pin Voltage VOUT Pin Voltage (FB Pin Voltage) LX Pin Voltage P_BST Pin Voltage Other Pin Voltage LX Pin Current EXT/1,2 Pin Current Continuous Total Power Dissipation Operating Ambient Temperature Storage Temperature SYMBOL VIN VOUT (VFB) VLX P_BST V~ ILX IEXT/1,2 Pd Topr Tstg RATINGS -0.3 ~ 12 -0.3 ~ 12 (-0.3 ~ VIN +0.3) VIN -12 ~ VIN +0.3 VIN -12 ~ VIN +0.3 -0.3 ~ VIN +0.3 700 50 300 -30 ~ +80 -40 ~ +125 Ta=25: UNITS V V V V V mA mA mW : : s Electrical Characteristics XC6376A303SR, XC6377A303SR PARAMETER Output Voltage Output Voltage2 Maximum Input Voltage Maximum Output Current Input Current Supply Current (oscillation stopped) Stand-by Current Lx SW ON Resistance Lx Leak Current Oscillator Frequency (Note1) Maximum Duty Ratio PFM Duty Ratio (Note2) Efficiency (Note3) Minimum Operating Voltage (UVLO Voltage) Soft-Start Time Circuit Protect Integration Time CE "High" Voltage CE "Low" Voltage SYMBOL VOUT1 VOUT2 VIN IOUTMAX IIN IDD ISTB RSWON ILXL FOSC MAXDTY PFMDTY EFFI VUVLO Tss TPRO VCEH VCEL Only CSS connected, VIN = output programmed voltage x 1.2, Time taken for CE to become "L" when VOUT changes to 0V Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "L" Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "H" Only CSS connected, VIN = output programmed voltage x 1.2, CE=0V, VOUT=VIN, EXT/1,2 pull down to 200, VEXT/1,2=VIN - 0.4V Only CSS connected, VIN = output programmed voltage x 1.2, CE=VIN, VOUT=output programmed voltage x 0.9, EXT/1,2 pull up to 200, VEXT/1,2=0.4V 38 Peripherals connected, VIN=output programmed voltage x 1.2, Peripherals connected, VIN=VOUT x 1.05, No load. XC6376 XC6377 (VOUT=3.0V, FOSC=300kHz) CONDITIONS Peripherals connected, VIN=output programmed voltage x 1.2, IOUT=120mA MIN TYP Ta=25: MAX UNITS V V V 1.320 1.950 52 26 1.5 0.69 82 39 2.5 0.94 2.0 255 100 15 300 345 mA mA A A A A kHz % % % 1.8 10.0 5.0 16.0 8.0 V msec msec V 0.20 52 V 2.925 3.000 3.075 VOUT1 +1.5% Peripherals connected, VIN=output programmed voltage x 1.6, VOUT1 -0.5% (when VIN 3.0V, VIN =3.0V) 10 500 e Only CSS connected, VIN = output programmed voltage x 1.2, VOUT= VIN, VLX=VIN Same as IDD. CE=0V Same as IDD except VOUT=output programmed voltage x0.9, VLX=VIN-0.2V, pull down LX to 10, CE=VIN Same as ISTB except VLX=0V Peripherals connected, measuring of EXT/1 waveform, VIN=VOUT1 +0.3V, IOUT=20mA Peripherals connected, No load. Same as VOUT 1 Only CSS connected, VIN = output programmed voltage x 0.9, CE= VIN, LX OFF voltage when VIN drops. 0.9 6.0 3.0 0.65 25 95 35 EXT/1,2 "H" ON Resistance REXTBH EXT/1,2 "L" ON Resistance REXTBL 31 41 Note 1: Refers to the oscillation frequency during PWM control. Note 2: Applies to the XC6377 series only (duty ratio when control changes to PFM) Note 3: EFFI = { [(output voltage) x (output current)] / [(input voltage) x (input current)]} x100 XC6376E, XC6376F, XC6377E, XC6377F The following parameter is to be added: PARAMETER VOUT Sink Current SYMBOL IVOUTL CONDITIONS Same as ISTB, VOUT=1.0V MIN 1.36 TYP MAX UNITS mA XC6376C, XC6376F, XC6377C, XC6377F The following parameter is to be excluded: Circuit Protect Integration Time (TPRO) s Electrical Characteristics XC6376A333SR, XC6377A333SR PARAMETER Output Voltage Output Voltage2 Maximum Input Voltage Maximum Output Current SYMBOL VOUT1 VOUT2 VIN IOUTMAX IIN IDD ISTB RSWON ILXL FOSC MAXDTY PFMDTY EFFI VUVLO Tss TPRO VCEH VCEL Only CSS connected, VIN = output programmed voltage x 1.2, Time taken for CE to become "L" when VOUT changes to 0V Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "L" Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "H" Only CSS connected, VIN = output programmed voltage x 1.2, CE=0V, VOUT=VIN, EXT/1,2 pull down to 200, VEXT/1,2=VIN - 0.4V Only CSS connected, VIN = output programmed voltage x 1.2, CE=VIN, VOUT=output programmed voltage x 0.9, EXT/1,2 pull up to 200, VEXT/1,2=0.4V 35 Peripherals connected, VIN=output programmed voltage x 1.2, Peripherals connected, VIN=VOUT x 1.05, No load. XC6376 XC6377 (VOUT=3.3V, FOSC=300kHz) CONDITIONS Peripherals connected, VIN=output programmed voltage x 1.2, IOUT=132mA MIN TYP Ta=25: MAX UNITS V V V 1.480 2.190 55 26 1.5 0.64 86 39 2.5 0.85 2.0 255 100 15 300 345 mA mA A A A A kHz % % % 1.8 10.0 5.0 16.0 8.0 V msec msec V 0.20 47 V 3.218 3.300 3.383 VOUT1 +1.5% Peripherals connected, VIN=output programmed voltage x 1.6, VOUT1 -0.5% (when VIN 3.0V, VIN =3.0V) 10 600 e Input Current Supply Current (oscillation stopped) Stand-by Current Lx SW ON Resistance Lx Leak Current Oscillator Frequency (Note1) Maximum Duty Ratio PFM Duty Ratio (Note2) Efficiency (Note3) Minimum Operating Voltage (UVLO Voltage) Soft-Start Time Circuit Protect Integration Time CE "High" Voltage CE "Low" Voltage Only CSS connected, VIN = output programmed voltage x 1.2, VOUT= VIN, VLX=VIN Same as IDD. CE=0V Same as IDD except VOUT=output programmed voltage x0.9, VLX=VIN-0.2V, pull down LX to 10, CE=VIN Same as ISTB except VLX=0V Peripherals connected, measuring of EXT/1 waveform, VIN=VOUT1 +0.3V, IOUT=20mA Peripherals connected, No load. Same as VOUT 1 Only CSS connected, VIN = output programmed voltage x 0.9, CE= VIN, LX OFF voltage when VIN drops. 0.9 6.0 3.0 0.65 25 95 35 EXT/1,2 "H" ON Resistance REXTBH EXT/1,2 "L" ON Resistance REXTBL 29 37 Note 1: Refers to the oscillation frequency during PWM control. Note 2: Applies to the XC6377 series only (duty ratio when control changes to PFM) Note 3: EFFI = { [(output voltage) x (output current)] / [(input voltage) x (input current)]} x100 XC6376E, XC6376F, XC6377E, XC6377F The following parameter is to be added: PARAMETER VOUT Sink Current SYMBOL IVOUTL CONDITIONS Same as ISTB, VOUT=1.0V MIN 1.45 TYP MAX UNITS mA XC6376C, XC6376F, XC6377C, XC6377F The following parameter is to be excluded: Circuit Protect Integration Time (TPRO) s Electrical Characteristics XC6376A503SR, XC6377A503SR PARAMETER Output Voltage Output Voltage2 Maximum Input Voltage Maximum Output Current Input Current Supply Current (oscillation stopped) Stand-by Current Lx SW ON Resistance Lx Leak Current Oscillator Frequency (Note1) Maximum Duty Ratio PFM Duty Ratio (Note2) Efficiency (Note3) Minimum Operating Voltage (UVLO Voltage) Soft-Start Time Circuit Protect Integration Time CE "High" Voltage CE "Low" Voltage SYMBOL VOUT1 VOUT2 VIN IOUTMAX IIN IDD ISTB RSWON ILXL FOSC MAXDTY PFMDTY EFFI VUVLO Tss TPRO VCEH VCEL Only CSS connected, VIN = output programmed voltage x 1.2, Time taken for CE to become "L" when VOUT changes to 0V Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "L" Only CSS connected, VIN = output programmed voltage x 1.2, VOUT=0V, Apply voltage to CE and measure EXT/1,2 "H" Only CSS connected, VIN = output programmed voltage x 1.2, CE=0V, VOUT=VIN, EXT/1,2 pull down to 200, VEXT/1,2=VIN - 0.4V Only CSS connected, VIN = output programmed voltage x 1.2, CE=VIN, VOUT=output programmed voltage x 0.9, EXT/1,2 pull up to 200, VEXT/1,2=0.4V 24 Peripherals connected, VIN=output programmed voltage x 1.2, Peripherals connected, VIN=VOUT x 1.05, No load. XC6376 XC6377 (VOUT=5.0V, FOSC=300kHz) CONDITIONS Peripherals connected, VIN=output programmed voltage x 1.2, IOUT=200mA MIN TYP Ta=25: MAX UNITS V V V 2.540 3.740 71 26 1.5 0.44 110 39 2.5 0.58 2.0 255 100 15 300 345 mA mA A A A A kHz % % % 1.8 10.0 5.0 16.0 8.0 V msec msec V 0.20 32 V 4.875 5.000 5.125 VOUT1 +1.5% Peripherals connected, VIN=output programmed voltage x 1.6, VOUT1 -0.5% (when VIN 3.0V, VIN =3.0V) 10 600 e Only CSS connected, VIN = output programmed voltage x 1.2, VOUT= VIN, VLX=VIN Same as IDD. CE=0V Same as IDD except VOUT=output programmed voltage x0.9, VLX=VIN-0.2V, pull down LX to 10, CE=VIN Same as ISTB except VLX=0V Peripherals connected, measuring of EXT/1 waveform, VIN=VOUT1 +0.3V, IOUT=20mA Peripherals connected, No load. Same as VOUT 1 Only CSS connected, VIN = output programmed voltage x 0.9, CE= VIN, LX OFF voltage when VIN drops. 0.9 6.0 3.0 0.65 25 95 35 EXT/1,2 "H" ON Resistance REXTBH EXT/1,2 "L" ON Resistance REXTBL 20 26 Note 1: Refers to the oscillation frequency during PWM control. Note 2: Applies to the XC6377 series only (duty ratio when control changes to PFM) Note 3: EFFI = { [(output voltage) x (output current)] / [(input voltage) x (input current)]} x100 XC6376E, XC6376F, XC6377E, XC6377F The following parameter is to be added: PARAMETER VOUT Sink Current SYMBOL IVOUTL CONDITIONS Same as ISTB, VOUT=1.0V MIN 1.85 TYP MAX UNITS mA XC6376C, XC6376F, XC6377C, XC6377F The following parameter is to be excluded: Circuit Protect Integration Time (TPRO) s Electrical Characteristics XC6376B103SR, XC6377B103SR PARAMETER Output Voltage Output Voltage2 Maximum Input Voltage Maximum Output Current SYMBOL VOUT1 VOUT2 VIN IOUTMAX IIN IDD ISTB RSWON ILXL FOSC MAXDTY PFMDTY EFFI VUVLO Tss TPRO VCEH VCEL Only CSS connected, VIN = 3.6V Time taken for CE to become "L" when VOUT changes to 0V Only CSS connected, VIN = 3.6V, FB=0V, Apply voltage to CE and measure EXT/1,2 "L" Only CSS connected, VIN = 3.6V, FB=0V, Apply voltage to CE and measure EXT/1,2 "H" Only CSS connected, CE=0V, VIN=3.6V, FB=1.2V, EXT/1,2 pull down to 200, VEXT/1,2=VIN - 0.4V Only CSS connected, CE=VIN, VIN=3.6V, FB=0.9V, EXT/1,2 pull up to 200, VEXT/1,2=0.4V 38 Peripherals connected, VIN=3.6V Peripherals connected, VIN=VOUT x 1.05, No load. Only CSS connected, VIN = 3.6V FB= 1.2V, VLX=VIN Same as IDD. CE=0V Only CSS connected, VIN=3.6V, CE=VIN, LX pull down to 10 VLX=VIN - 0.2V, FB=0.9V Same as ISTB except VLX=0V Peripherals connected, measuring of EXT/1 waveform, VIN=VOUT1 +0.3V, IOUT=20mA Peripherals connected, No load. Same as VOUT 1 Only CSS connected. CE= VIN, FB=0.9V, LX OFF voltage when VIN drops. 0.9 6.0 3.0 0.65 0.20 52 10.0 5.0 255 100 15 300 XC6376 XC6377 (VOUT=3.0V(when programmed), FOSC=300kHz) CONDITIONS Peripherals connected, VIN=3.6V, IOUT=120mA Peripherals connected, VIN=4.8V MIN TYP Ta=25: MAX UNITS V V V 1.320 1.950 52 26 1.5 0.69 82 39 2.5 0.94 2.0 345 mA mA A A A A kHz % % % 1.8 16.0 8.0 V msec msec V V 2.940 3.000 3.060 VOUT1 -0.5% 10 500 VOUT1 +1.5% e Input Current Supply Current (oscillation stopped) Stand-by Current Lx SW ON Resistance Lx Leak Current Oscillator Frequency (Note1) Maximum Duty Ratio PFM Duty Ratio (Note2) Efficiency (Note3) Minimum Operating Voltage (UVLO Voltage) Soft-Start Time Circuit Protect Integration Time CE "High" Voltage CE "Low" Voltage 25 95 35 EXT/1,2 "H" ON Resistance REXTBH EXT/1,2 "L" ON Resistance REXTBL 31 41 Peripherals: RFB1=400k, RFB2=200k, CFB=100pF Note 1: Refers to the oscillation frequency during PWM control. Note 2: Applies to the XC6377 series only (duty ratio when control changes to PFM) Note 3: EFFI = { [(output voltage) x (output current)] / [(input voltage) x (input current)]} x100 XC6376D, XC6376D The following parameter is to be excluded: Circuit Protect Integration Time (TPRO) s Notes 1. MAXIMUM OUTPUT CURRENT IOUTMAX The maximum output current of a step-down DC/DC converter can be calculated from the values of the switching transistor's ON resistance (RSWON), the DC resistance of the coil (DCR) and the wiring resistance between the input and output pins (RETC). IOUTMAX=(VIN - VOUT) / (RSWON + DCR + RETC) The coil's DCR value will be 0.18(max.) with the CD54 22H (catalog value). If output current should exceed the above calculated value for IOUTMAX a condition of maximum duty will exist. Please use coils and Schottky diodes that have an ample output current (IOUT) margin over the stated approved currents and check the coil's current frequency in actual operation. 2. BOARD WIRING Peripherals should be located as close as possible to the IC and should be connected with low impedance traces. Note that high current levels flow through the VIN - IC - coil - VOUT line. Make the ground pattern as large as possible and connect capacitor CL between the ground pin and the VOUT pin with a low impedance. e 3. INTEGRAL CIRCUIT PROTECTION Should the output voltage drop as a result of overload, the IC will operate in a maximum duty state. If the TPRO time (5 msec typ.) is exceeded the CE pin will be reset to ground level and the soft-start routine will resume. If the overload condition continues then the following steps will be repeated. Circuit protection activates - CE pin reset - soft-start routine resumes - circuit protection activates -etc. As stated, when the current drawn exceeds the maximum output current (IOUTMAX) as calculated above, maximum duty will exist. When the input/output voltage differential is minimal even a comparatively small output current will trigger the protection circuit so please be careful. For those customers who require the P channel power MOSFET to be enabled at any time and the protect circuit to not operate during low VIN periods, versions of the series without protection are also available (XC6376C, D, F types and XC6377C, D, F types) Note : Integral circuit protection performs the basic function of informing external components of the existence of a continuous state of overload in connection with temporary drops in the level of VOUT (CE). Therefore, should output short to ground level and a state of overload continue, ample circuit protection cannot be provided. In such cases, as there is the possibility that the IC and/or the peripherals may be damaged, it is recommended that output be switched off via the CE pin. 4. SOFT-START, CHIP ENABLE CIRCUITS (CE PIN) In order to charge the soft-start capacitor (CSS) at the CE pin, a fixed current of about 1A has been internally set-up. Therefore, when using the CE function (stand-by operations) please be aware of the possibilites of leak current from the transistor's open collector (or open drain) connection. We recommend that a capacitor of at least 100pF be connected. Although the IC will still function with CSS omitted and the CE pin connected to the VIN pin, there exists the possibility that large overshoot input voltages and/or rush currents will occur when the power is switched on which may cause instability. The same problem may also arise if the CE pin is driven from a CMOS output , so it is recommended that the CE pin be driven from an open collector (or open drain). Should the CE pin be driven from a CMOS output however, a resistor should be fitted between the CE pin and the output and a soft-start capacitor (CSS) should be connected. Measuring operational stability is also necessary. Note : Even if the CE function is not being used, a soft-start capacitor (CSS) of more than 100pF should still be connected. 5. P-CHANNEL BOOST CIRCUIT Attaching a capacitor (CBST) and a diode (SD2) as displayed in the figure right, allows the gate voltage of an internal Pch power MOSFET to be driven to a negative voltage value. Since LX SW ON resistance (RSWON) becomes smaller, the efficiency at high output currents can be improved. On the other hand, efficiency during light loads will drop due to losses as a result of CBST's charging and discharging. CBST : 2200pF (ceramic capacitor) SD2 : MA729 (Schottky diode, Matsushita) Note : The voltage between VIN and P-BST should not exceed 10V (absolute max. 12V). With higher VIN values, take such countermeasures as clamping or using a 9V Zener diode. CBST 1 2 3 4 SD2 ZD 8 7 6 5 s Notes (continued) 6. EXT / 1, EXT / 2 PINS As the EXT / 1 and EXT / 2 pins are provided, external transistor drives and various application circuits can be handled. EXT / 1 follows the same timing pattern as a P channel power MOSFET ("L" in the ON mode) whereas EXT / 2 functions in a 100 nsec blank clock timing pattern (N.B. EXT / 2 changes from "H to L" 100 nsec before EXT /1 but 100 nsec after EXT / 1 with "L to H" changes.) e.g. The drawing of large output currents can be handled by connecting an external, low ON resistance, Pch power MOSFET. In such cases we also recommend that the FET gate be connected to EXT / 1, the source to VIN and the drain to Lx in line with the typical application circuit examples provided. The EXT /1 pin can be driven to a gate capacitance of up to 1000pF. e 7. U. V. L. O CIRCUIT Below the minimum operating voltage (VUVLO) operations shut down and, along with the Pch power MOSFET being set to OFF, Ext /1 and EXT /2 will be "H" . (If using an external transistor, the transistor will be set to OFF.) 8. VOUT RESET FUNCTION A function that pulls VOUT to ground during stand-by (CE "L") is available (XC6376E). Note that this function is not available with externally set-up output voltage types (FB). 9. CAPACITOR CIN Sudden current changes at ground or power supply that are common to step-down DC/DC converters during switching may cause the IC's operations to become unstable depending upon the degree to which the IC's power supply voltage changes, which in turn is affected by the wiring's impedance level. It is therefore recommended that a power supply ripple rejection use capacitor (CIN) be connected between the IC's VIN and GND pins. s Standard Circuits 1. Output Voltage Internally Set-up Type (VOUT) VIN 1 CIN CE/ 3 4 6 VOUT 5 CL CSS + + 2 8 7 L SD1 e External Components : L : 22H (Sumida CD54, FOSC=300kHz) 47H (Sumida CD75, FOSC=180kHz) 10H (Sumida CD54, FOSC=500kHz) SD1 : MA735 (Schottky Diode, Matsushita) CL : 10V 47F (Tantalum capacitor, Nichicon F93) CSS : 4700pF (Ceramic capacitor, FOSC=300kHz, 180kHz) 0.01F (Ceramic capacitor, FOSC=500kHz) CIN : 16V 47F (Tantalum capacitor, Nichicon F93) Note : Please increase capacitance value (CIN) when necessary 2. Output Voltage Externally Set-up Type (FB) VIN 1 CIN CE/ 3 4 6 5 RFB2 CSS CL + + 2 8 7 CFB RFB1 VOUT L SD1 External Components : L : 22H (Sumida CD54, FOSC=300kHz) 47H (Sumida CD75, FOSC=180kHz) 10H (Sumida CD54, FOSC=500kHz) : MA735 (Schottky Diode, Matsushita) : 10V 47F (Tantalum capacitor, Nichicon F93) : 4700pF (Ceramic capacitor, FOSC=300kHz, 180kHz) 0.01F (Ceramic capacitor, FOSC=500kHz) : 16V 47F (Tantalum capacitor, Nichicon F93) : Please set-up so that RFB1 / RFB2 = VOUT - 1 (VOUT = set-up output voltage) and ensure that RFB1 + RFB2 2M. N.B. In actual operation please set-up so that the FB pin will be equal to 1.0V : Please set-up so that { f = 1 / (2 x CFB x RFB1)} will be in the range of 1 ~ 20kHz (5kHz normal ) e.g. If VOUT = 3.0V then RFB1 = 400k, FFB2 = 200k, CFB = 100pF SD1 CL CSS CIN RFB CFB Note : Please increase capacitance value (CIN) when necessary s Typical Application Circuits 1. Large Current Output Circuit (P channel power MOSFET external) VIN 1 CIN CE/ + 2 3 4 8 7 SD1 L 6 VOUT 5 CL CSS + e External Components : L SD1 CL CSS CIN Tr : 22H (Sumida CD54, FOSC=300kHz) : U2FWJ44N (Diode, Toshiba) : 10V 47F +47F (Tantalum capacitor, Nichicon F93) : 4700pF (Ceramic capacitor) : 16V 47F (Tantalum capacitor, Nichicon F93) or 0.1F (Ceramic capacitor) : XP162A01B5PR or XP132A0265SR (Torex) Note : In order to reduce impedance we recommend use of a capacitor (CIN) with a large capacitance value or a ceramic capacitor with a low ESR value. Please insert a by-pass capacitor of more than 0.1F between pin Numbers 1 and 3. s Electrical Characteristics (1) OUTPUT VOLTAGE vs. OUTPUT CURRENT XC6377A333 XC6376A333 OUTPUT VOLTAGE:VOUT (V) OUTPUT VOLTAGE:VOUT (V) e OUTPUT CURRENT :IOUT (mA) OUTPUT CURRENT :IOUT (mA) XC6377A333 XC6377A333 OUTPUT VOLTAGE:VOUT (V) OUTPUT CURRENT :IOUT (mA) OUTPUT VOLTAGE:VOUT (V) OUTPUT CURRENT :IOUT (mA) XC6377A503 XC6376A503 OUTPUT VOLTAGE:VOUT (V) OUTPUT CURRENT :IOUT (mA) OUTPUT VOLTAGE:VOUT (V) OUTPUT CURRENT :IOUT (mA) s Electrical Characteristics (2) EFFICIENCY vs. OUTPUT CURRENT XC6377A333 XC6376A333 EFFICIENCY:EFFI(%) e OUTPUT CURRENT :IOUT (mA) EFFICIENCY:EFFI(%) OUTPUT CURRENT :IOUT (mA) XC6377A333 XC6377A333 EFFICIENCY:EFFI(%) OUTPUT CURRENT :IOUT (mA) EFFICIENCY:EFFI(%) OUTPUT CURRENT :IOUT (mA) XC6377A503 XC6376A503 EFFICIENCY:EFFI(%) OUTPUT CURRENT :IOUT (mA) EFFICIENCY:EFFI(%) OUTPUT CURRENT :IOUT (mA) s Electrical Characteristics (3) OUTPUT VOLTAGE vs. AMBIENT TEMPERATURE (4) SUPPLY CURRENT vs. AMBIENT TEMPERATURE XC6377A333 OUTPUT VOLTAGE :VOUT1, VOUT2(V) XC6377A333 SUPPLY CURRENT :IDD(A) e AMBIENT TEMP. :Ta(:) AMBIENT TEMP. :Ta(:) (5) STAND-BY CURRENT vs. AMBIENT TEMPERATURE (6) LX SWITCH ON RESISTANCE vs. AMBIENT TEMPERATURE XC6377A333 LX SWITCH ON RESISTANCE :RSWON() XC6377A333 OUTPUT VOLTAGE :VOUT(V) AMBIENT TEMP. :Ta(:) AMBIENT TEMP. :Ta(:) (7) OSCILLATION FREQUENCY vs. AMBIENT TEMPERATURE (8) PFM DUTY RATIO vs. AMBIENT TEMPERATURE XC6377A333 OSCILLATION FREQUENCY :FOSC(kHz) XC6377A333 AMBIENT TEMP. :Ta(:) PFM DUTY RATIO :PFMDTY(%) AMBIENT TEMP. :Ta(:) s Electrical Characteristics (9) EFFICIENCY vs. AMBIENT TEMPERATURE (10) MINIMUM OPERATING VOLTAGE vs. AMBIENT TEMPERATURE XC6377A333 MIN. OPERATING VOLTAGE :VUVLO(V) XC6377A333 e EFFICIENCY :EFFI(%) AMBIENT TEMP. :Ta(:) AMBIENT TEMP. :Ta(:) (11) SOFT START TIME vs. AMBIENT TEMPERATURE (12) CE "L" VOLTAGE vs. AMBIENT TEMPERATURE XC6377A333 XC6377A333 SOFT START TIME :TSS(V) AMBIENT TEMP. :Ta(:) CE "L" VOLTAGE:VCEL(V) AMBIENT TEMP. :Ta(:) (13) CE "H" VOLTAGE vs. AMBIENT TEMPERATURE XC6377A333 CE "H" VOLTAGE :VCEH(V) AMBIENT TEMP. :Ta(:) s Electrical Characteristics (14) LOAD TRANSIENT RESPONSE XC6377A333 XC6377A333 OUTPUT CURRENT IOUT(mA) Output Voltage OUTPUT CURRENT IOUT(mA) OUTPUT CURRENT IOUT(mA) OUTPUT CURRENT IOUT(mA) Output Voltage OUTPUT VOLTAGE VOUT(V) OUTPUT VOLTAGE VOUT(V) e Output Current Output Current TIME (0.5msec/div) TIME (20msec/div) XC6377A333 XC6377A333 OUTPUT VOLTAGE VOUT(V) OUTPUT VOLTAGE VOUT(V) Output Voltage OUTPUT CURRENT IOUT(mA) Output Voltage Output Current Output Current TIME (0.5msec/div) TIME (20msec/div) XC6377A333 XC6377A333 OUTPUT CURRENT IOUT(mA) Output Voltage OUTPUT VOLTAGE VOUT(V) OUTPUT VOLTAGE VOUT(V) Output Voltage Output Current Output Current TIME (0.5msec/div) TIME (0.5msec/div) |
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