R1202L521A-TR

R1202x Series STEP-UP DC/DC CONVERTER with SHUTDOWN FUNCTION NO.EA-255-210322 OUTLINE The R1202x Series are CMOS-based PWM step-up DC/DC converter ICs with low supply current. Each of these ICs consists of an NMOS FET, NPN transistor, an oscillator, a PWM comparator, a voltage reference unit, an error amplifier, a current limit circuit, an under voltage lockout circuit (UVLO), an over-voltage protection circuit (OVP), a soft-start circuit, a Maxduty limit circuit, and a thermal shutdown protection circuit. By simply using an inductor, a resistor, and capacitors as external components, a high-efficiency step-up DC/DC converter can be easily configured. At the standby mode, a rectifier transistor can separate the output from the input. The R1202x Series include a thermal shut-down circuit and an under-voltage lockout circuit (UVLO) which separate the output from the input to shut down the current when the overheat caused when the output is connected to the Gnd is detected and also during the UVLO detection. As other protection functions, the R1202x Series contain a cycle by cycle current limit circuit that limits the Lx peak current, and an over-voltage protection circuit (OVP) that detects the output overvoltage. The R1202x Series offer three versions: the R1202xxxxA/B versions, which are optimized for constant-voltage power supply and the R1202xxxxD version, which is optimized to drive serial white LEDs with constant current. While the R1202xxxxA version discharges the VOUT output to 0V at the shutdown, the R1202xxxxB version doesn’t. The brightness of the white LEDs can be adjusted quickly by applying a PWM signal (200Hz to 300kHz) to the CE pin. The R1202x Series are available in DFN1616-6B and TSOT-23-6 packages. FEATURES • Input Voltage Range ......................................... 2.3V to 5.5V (R1202xxxxA/B) 1.8V to 5.5V (R1202xxxxD) • Supply Current ................................................. Typ. 800µA • Standby Current ............................................... Max. 5µA • Feedback Voltage ............................................ 1.0V±15mV (R1202xxxxA/B) 0.2V±10mV (R1202xxxxD) • Oscillator Frequency ........................................ Typ. 1.2MHz • Maximum Duty Cycle ....................................... Typ. 91% • UVLO Function ............................................... Typ.2.0V (Hys.Typ.0.2V) (R1202xxxxA/B) Typ.1.6V (Hys.Typ.0.1V) (R1202xxxxD) • Lx Current Limit Function ................................. Select from 350mA, 700mA • Over Voltage Protection ................................... Select from 14V-23V (Refer the Selection Guide) • LED dimming control for R1202xxxxD ............. by external PWM signal (Frequency 200Hz to 300kHz) • Thermal Protection Function .......................... Typ.150ºC(Hys.Typ.50ºC) • Built-in Auto Discharge Function ...................... R1202xxxxA • NMOS ON Resistance ..................................... 1.35Ω • Packages ......................................................... DFN1616-6B, TSOT-23-6 APPLICATION • Constant Voltage Power Source for portable equipment • OLED power supply for portable equipment • White LED Backlight for portable equipment 1 R1202x NO.EA-255-210322 SELECTION GUIDE The OVP threshold voltage, current limit, package and VFB/Auto discharge are user-selectable options. Product Name R1202Lyz1∗-TR R1202Nyz3∗-TR-FE Package Quantity per Reel Pb Free Halogen Free DFN1616-6B 5,000 pcs Yes Yes TSOT-23-6 3,000 pcs Yes Yes y : Designation of OVP threshold (3) 14V : R1202xxxxA/B/D (4) 17V : R1202xxxxA/B (5) 19V : R1202xxxxA/B (6) 21V : R1202xxxxA/B (7) 23V : R1202xxxxA/B/D z : Designation of current limit (1) 350mA (2) 700mA ∗ : Designation of VFB, auto discharge function A B D VFB 1.0V 1.0V 0.2V Auto discharge ○ × × Auto-discharge function quickly lowers the output voltage to 0V, when the chip enable signal is switched from the active mode to the standby mode, by releasing the electrical charge accumulated in the external capacitor. 2 R1202x NO.EA-255-210322 BLOCK DIAGRAMS R1202xxxxA VIN VFB Err. Amp. + – vref UVLO PWM Comp. + – VOUT LX R S Q Switch Control Driver Control Oscillator Soft-start Slope Compensation OVP Current Limit Current sense Thermal Shutdown ∑ CE CE GND R1202xxxxB VIN VFB Err. Amp. + – vref UVLO PWM Comp. + – R S Q Switch Control Driver Control OVP Oscillator Soft-start VOUT LX Slope Compensation Current Limit Current sense Thermal Shutdown ∑ CE CE GND 3 R1202x NO.EA-255-210322 R1202xxxxD Err. Amp. + – vref UVLO PWM Comp. + – R S Q Switch Control Driver Control OVP Oscillator PWM Cntrl VOUT LX VIN VFB EN Slope Compensation Shutdown delay ∑ Current Limit Current sense Thermal Shutdown CE CE GND 4 R1202x NO.EA-255-210322 PIN DESCRIPTIONS • DFN1616-6B Top View 6 5 • TSOT-23-6 Bottom View 4 4 5 6 2 3 3 2 4 6 (mark side) ∗ 1 5 1 1 2 3 DFN1616-6B Pin No Symbol Pin Description 1 CE Chip Enable Pin ("H" Active) 2 VFB Feedback Pin 3 LX Switching Pin (Open Drain Output) 4 GND 5 VIN 6 VOUT Ground Pin Input Pin Output Pin ∗) The tab is substrate level (GND). The tab is better to be connected to the GND, but leaving it open is also acceptable. TSOT-23-6 Pin No Symbol Pin Description 1 CE Chip Enable Pin ("H" Active) 2 VOUT Output Pin 3 VIN Input Pin 4 LX Switching Pin (Open Drain Output) 5 GND 6 VFB Ground Pin Feedback Pin 5 R1202x NO.EA-255-210322 ABSOLUTE MAXIMUM RATINGS Symbol (GND=0V) Item Rating Unit VIN VIN Pin Voltage -0.3 to 6.5 V VCE CE Pin Voltage -0.3 to 6.5 V VFB VFB Pin Voltage -0.3 to 6.5 V VOUT VOUT Pin Voltage -0.3 to 25 V VLX LX Pin Voltage -0.3 to 25 V ILX LX Pin Current 1000 mA PD Power Dissipation * DFN1616-6B (JEDEC STD. 51-7 Test Land Pattern) 2400 TSOT-23-6 (Standard Test Land Pattern) 460 mW Tj Junction Temperature Range -40 to 125 °C Tstg Storage Temperature Range -55 to 125 °C ∗) Refer to POWER DISSIPATION for detailed information. ABSOLUTE MAXIMUM RATINGS Electronic and mechanical stress momentarily exceeded absolute maximum ratings may cause permanent damage and may degrade the life time and safety for both device and system using the device in the field. The functional operation at or over these absolute maximum ratings is not assured. RECOMMENDED OPERATING CONDITIONS Symbol Item Rating VIN Operating Input Voltage Ta Operating Temperature Range Unit R1202xxxxA/B 2.3 V to 5.5 V V R1202xxxxD 1.8 V to 5.5 V V −40 to 85 °C RECOMMENDED OPERATING CONDITIONS All of electronic equipment should be designed that the mounted semiconductor devices operate within the recommended operating conditions. The semiconductor devices cannot operate normally over the recommended operating conditions, even if they are used over such conditions by momentary electronic noise or surge. And the semiconductor devices may receive serious damage when they continue to operate over the recommended operating conditions. 6 R1202x NO.EA-255-210322 ELECTRICAL CHARACTERISTICS R1202x Symbol IDD (Ta=25°C) Item Conditions Min. Typ. Max. Unit Supply Current VIN=5.5V , VFB=0V , LX at no load 0.8 1.2 mA Istandby Standby Current VIN=5.5V , VCE=0V 1.0 5.0 µA VUVLO1 UVLO Detect Threshold Voltage VIN falling VUVLO2 UVLO Release Voltage R1202xxxxA/B 1.9 2.0 2.1 V R1202xxxxD 1.5 1.6 1.7 V R1202xxxxA/B VUVLO1 +0.2 2.3 V R1202xxxxD VUVLO1 +0.1 1.8 V VIN rising VCEH CE Input Voltage "H" VCEL CE Input Voltage "L" RCE CE Pull Down Resistance VFB VFB Voltage Accuracy VCE=3.6V VFB Voltage Temperature Coefficient VCE=3.6V, -40°C < = Ta < = 85°C VFB Input Current VIN=5.5V, VFB=0V or 5.5V tstart Soft-start Time *R1202xxxxA/B 2.0 ms RON Driver ON Resistance VCE=3.6V, ILX=100mA 1.35 Ω IOFF Driver Leakage Current VLX=22V ILIM Driver Current Limit VIN=3.6V VF NPN Forward Voltage ILX=100mA ISWOFF1 NPN Leakage Current 1 VOUT=22V, VLX=0V 10 µA ISWOFF2 NPN Leakage Current 2 VOUT=0V, VLX=5.5V 3 µA Oscillator Frequency VIN=3.6V, VFB=0V 1400 kHz ∆VFB/∆Ta IFB fosc VIN=5.5V 1.5 V 0.5 1200 kΩ R1202xxxxA/B 0.985 1.000 1.015 R1202xxxxD 0.19 0.2 0.21 0.1 3.0 R1202xx1xx 250 350 450 R1202xx2xx 500 700 900 0.8 1000 1200 V ppm/ °C ±150 -0.1 V µA µA mA V 7 R1202x NO.EA-255-210322 (Ta=25ºC) Symbol Maxduty VOVP1 Item Maximum Duty Cycle OVP Detect Voltage Conditions Min. Typ. 86 91 R1202x3xxA/B/D 13.2 14 14.8 R1202x4xxA/B 16.2 17 17.8 R1202x5xxA/B 18.2 19 19.8 R1202x6xxA/B 20.2 21 21.8 R1202x7xxA/B/D 22.2 23 VOVP1 -1.1 VOVP1 -1.3 VOVP1 -1.4 VOVP1 -1.5 VOVP1 -1.7 23.8 VIN=3.6V, VFB=0V VIN=3.6V, VOUT rising R1202x3xxA/B/D R1202x4xxA/B VOVP2 OVP Release Voltage VIN=3.6V, VOUT falling R1202x5xxA/B R1202x6xxA/B R1202x7xxA/B/D Max. Unit % V V TTSD Thermal Shutdown Detect Temperature VIN=3.6V 150 °C TTSR Thermal Shutdown Release Temperature VIN=3.6V 100 °C 8 R1202x NO.EA-255-210322 THEORY OF OPERATION Operation of Step-Up DC/DC Converter and Output Current i2 VIN IOUT Diode L VOUT i1 Lx Tr CL GND Discontinuous mode Continuous mode IL ILmax IL ILmax ILmin ILmin topen t toff ton T=1/fosc t ton toff T=1/fosc There are two operation modes of the step-up PWM control-DC/DC converter. That is the continuous mode and discontinuous mode by the continuousness inductor. When the transistor turns ON, the voltage of inductor L becomes equal to VIN voltage. The increase value of inductor current (i1) will be ∆i1 = VIN × ton / L ........................................................................................................... Formula 1 As the step-up circuit, during the OFF time (when the transistor turns OFF) the voltage is continually supply from the power supply. The decrease value of inductor current (i2) will be ∆i2 = (VOUT − VIN) × topen / L ........................................................................................... Formula 2 9 R1202x NO.EA-255-210322 At the PWM control-method, the inductor current become continuously when topen=toff, the DC/DC converter operate as the continuous mode. In the continuous mode, the variation of current of i1 and i2 is same at regular condition. VIN × ton / L = (VOUT - VIN) × toff / L ................................................................................... Formula 3 The duty at continuous mode will be duty (%)= ton / (ton + toff) = (VOUT - VIN) / VOUT ................................................................. Formula 4 The average of inductor current at tf = toff will be IL(Ave.) = VIN × ton / (2 × L) ............................................................................................ Formula 5 If the input voltage = output voltage, the IOUT will be IOUT = VIN2 × ton / (2 × L × VOUT) ....................................................................................... Formula 6 If the IOUT value is large than above the calculated value (Formula 6), it will become the continuous mode, at this status, the peak current (ILmax) of inductor will be ILmax = IOUT × VOUT / VIN + VIN × ton / (2 × L) .................................................................... Formula 7 ILmax = IOUT × VOUT / VIN + VIN × T × (VOUT - VIN) / (2 × L × VOUT)....................................... Formula 8 The peak current value is larger than the IOUT value. In case of this, selecting the condition of the input and the output and the external components by considering of ILmax value. The explanation above is based on the ideal calculation, and the loss caused by LX switch and the external components are not included. The actual maximum output current will be between 50% and 80% by the above calculations. Especially, when the IL is large or VIN is low, the loss of VIN is generated with on resistance of the switch. Moreover, it is necessary to consider Vf of the diode (approximately 0.8V) about VOUT. 10 R1202x NO.EA-255-210322 Soft-Start R1202xxxxA/B After inputting "H" to the CE pin, the error amplifier in the DC/DC converter starts from 0V and slowly rises with a time (typ. 2ms) until the set output voltage is reached. However, immediately after startup, (the input voltage (VIN) – NPN Forward voltage) is output without the soft start control. R1202xxxxD By gradually increasing the duty of the PWM signal input to the CE pin, the LED current (luminance) can be slowly increased in the same way as the soft start operation. Protect Function If the over current is detected, internal mosfet will turn-off soon. At the next operating period, mosfet will turn-on again and continue to watch the current. The UVLO function and the thermal shutdown function are turned off the NMOS-driver and NPN-transister when the VIN decreases more than the UVLO detect threshold voltage or the inside of IC exceeds the thermal shutdown detect temperature, and reset IC when the VIN rises more than the UVLO release voltage or the inside of IC falls below the thermal shutdown release temperature, and restart the operation. Shutdown At standby mode, the output is completely separated from the input and shutdown by the NPN transistor of internal IC. However, the leakage current is generated when the LX pin voltage is higher than VIN pin voltage at standby mode. R1202xxxxA (with auto discharge function): In the term of standby mode, the switch between VOUT to GND is turned ON and output capacitor is discharged. 11 R1202x NO.EA-255-210322 APPLICATION INFORMATION Typical Applications L1 10µH~22µH L1 10µH~22µH C1 1µF C1 1µF VIN LX CE VOUT R2 GND VFB C3 R3 C2 1µF VIN LX CE VOUT GND VFB R1 R1202xxxxA/B C2 0.22µF R1 10Ω R1202xxxxD  Selection of Inductor The peak current of the inductor at normal mode can be estimated as the next formula when the efficiency is 80%. ILmax = 1.25 × IOUT × VOUT / VIN + 0.5 × VIN × (VOUT - VIN) / (L × VOUT × fosc) In the case of start-up or dimming control by CE pin, inductor transient current flows, and the peak current of it must be equal or less than the current limit of the IC. The peak current should not beyond the rated current of the inductor. The recommended inductance value is 10µH -22µH. Table 1 Peak current value in each condition VIN (V) 3 3 3 3 Condition VOUT (V) IOUT (mA) 14 20 14 20 21 20 21 20 L (µH) 10 22 10 22 ILmax (mA) 215 160 280 225 Table 2 Recommended inductors L (µH) 10 10 10 10 10 22 22 22 22 Part No. LQH32CN100K53 LQH2MC100K02 VLF3010A-100 VLS252010-100 VLF403212MT-100M LQH32CN220K53 LQH2MC220K02 VLF3010A-220 VLF504015MT-220M Rated current (mA) 450 225 490 520 900 250 185 330 930 Size (mm) 3.2x2.5x1.55 2.0x1.6x0.9 2.8x2.6x0.9 2.5x2.0x1.0 4.0×3.2×1.2 3.2x2.5x1.55 2.0x1.6x0.9 2.8x2.6x0.9 5.0×4.0×1.5 12 R1202x NO.EA-255-210322  Selection of Capacitor Set 1µF or more value bypass capacitor C1 between VIN pin and GND pin as close as possible. R1202xxxxA/R1202xxxxB Set 1µF – 4.7µF or more capacitor C2 between VOUT and GND pin. Table 3-A Recommended components for R1202xxxxA/R1202xxxxB C1 C2 C3 R1 R2 R3 Rated voltage(V) Part No. 6.3 25 25 CM105B105K06 GRM21BR11E105K 22pF For VOUT Setting For VOUT Setting 2kΩ If the transient drop of output voltage by the load fluctuation is large and exceeds the allowable range in above setting, refer to Table 3-B to change the capacitors of C2 and C3 for the response improvement and the transient voltage drop reduction. Table 3-B Recommended components for R1202xxxxA/R1202xxxxB C1 C2 C3 R1 R2 R3 Rated voltage(V) Part No. 6.3 50 25 CM105B105K06 GRM31CR71H475M 220pF For VOUT Setting For VOUT Setting 2kΩ R1202xxxxD Set 0.22µF or more capacitor C2 between VOUT and GND pin. The rated voltage of C2 should be 25V or more. Table 4 Recommended components for R1202xxxxD C1 C2 Rated voltage(V) Part No. 6.3 25 CM105B105K06 GRM21BR11E224 13 R1202x NO.EA-255-210322  External Components Setting If the spike noise of VOUT may be large for R1202xxxxA/B, the spike noise may be picked into VFB pin and make the operation unstable. In this case, use a R3 of the resistance value in the range from 1kΩ to 5kΩ to reduce a noise level of VFB.  The Method of Output Voltage Setting (R1202xxxxA/B) The output voltage (VOUT) can be calculated with divider resistors (R1 and R2) values as the following formula: Output Voltage (VOUT) = VFB × (R1 + R2) / R1 The total value of R1 and R2 should be equal or less than 300kΩ. Make the VIN and GND line sufficient. The large current flows through the VIN and GND line due to the switching. If this impedance (VIN and GND line) is high, the internal voltage of the IC may shift by the switching current, and the operating may become unstable. Moreover, when the built-in LX switch is turn OFF, the spike noise caused by the inductor may be generated. As a result of this, recommendation voltage rating of capacitor (C2) value is equal 1.5 times larger or more than the setting output voltage.  LED Current setting (R1202xxxxD) When CE pin input is "H" (Duty=100%), LED current can be set with feedback resistor (R1) ILED = VFB / R1  LED Dimming Control (R1202xxxxD) The LED brightness can be controlled by inputting the PWM signal to the CE pin. If the CE pin input is "L" in the fixed time (Typ.0.5ms), the IC becomes the standby mode and turns OFF LEDs. The current of LEDs can be controlled by Duty of the PWM signal of the input CE pin. The current of LEDs when High-Duty of the CE input is "Hduty" reaches the value as calculatable following formula. ILED = Hduty × VFB / R1 The frequency of the PWM signal is using the range between 200Hz to 300kHz. When controlling the LED brightness by the PWM signal of 20kHz or less, the increasing or decreasing of the inductor current might be make a sounds in the hearable sound wave area. In that case, please use the PWM signal in the high frequency area. CE Hduty VFB R1 Dimming control by CE pin input 14 R1202x NO.EA-255-210322  ILED accuracy (R1202xxxxD) LED current (ILED) is affected by the offset voltage of the error amplifier in the DC/DC converter. LED might turn off due to the offset voltage variation, when brightness is controlled by low PWM duty cycle. It is recommended to input PWM signal with 10% or more duty cycle to prevented LED turn off(Ta=25℃). The table below shows the ILED accuracy at low PWM duty cycle input (low brightness). ILED accuracy when low PWM Duty is applied (R1 = 10 Ω) ILED Max. PWM Duty applied to CE Pin ILED Min. 10% (Frequency = 20kHz to 300kHz) 0.1mA (1) 5.1mA(1) (1) Design guaranteed value (Ta = 25 ºC) 15 R1202x NO.EA-255-210322 TECHNICAL NOTES  Current Path on PCB The current paths in an application circuit are shown in Fig. 1 and 2. A current flows through the paths shown in Fig. 1 at the time of MOSFET-ON, and shown in Fig. 2 at the time of MOSFET-OFF. In the paths pointed with red arrows in Fig. 2, current flows just in MOSFET-ON period or just in MOSFET-OFF period. Parasitic impedance / inductance and the capacitance of these paths influence stability of the system and cause noise outbreak. So please minimize this side effect. In addition, please shorten the wiring of other current paths shown in Fig. 1 and 2 except for the paths of LED load.  Layout Guide for PCB ⋅ Please shorten the wiring of the input capacitor (C1) between VIN pin and GND pin of IC. The GND pin should be connected to the strong GND plane. ⋅ The area of LX land pattern should be smaller. ⋅ Please put output capacitor (C2) close to the VOUT pin. ⋅ Please make the GND side of output capacitor (C2) close to the GND pin of IC. MOSFET-ON Load Load Fig. 1 Fig. 2 MOSFET-OFF 16 R1202x NO.EA-255-210322  PCB Layout ・PKG:DFN1616-6B pin R1202LxxxA/R1202LxxxB/R1202LxxxD typical board layout Top Layer Back Layer ・PKG: TSOT-23-6 pin R1202NxxxA/R1202NxxxB/R1202NxxxD Typical Board Layout Top Layer Back Layer U1-● indicates the position of No.1 pin. 17 R1202x NO.EA-255-210322 TYPICAL CHARACTERISTICS 1) Efficiency vs. Output Current (R1202N723A) VOUT=10V, L=22µH (LQH32CN220K53) 90 90 85 85 80 80 Efficiency (%) Efficiency (%) VOUT=10V, L=10µH (LQH32CN100K53) 75 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 75 70 65 55 50 50 0 5 10 15 Output Current (mA) 0 20 85 85 80 80 Efficiency (%) 90 75 70 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 15 20 75 70 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 65 60 55 50 50 0 5 10 15 20 0 5 Output Current (mA) 85 85 80 80 Efficiency (%) 90 75 70 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 5 10 Output Current (mA) 20 15 75 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 50 0 15 VOUT=20V, L=22µH (LQH32CN220K53) 90 65 10 Output Current (mA) VOUT=20V, L=10µH (LQH32CN100K53) Efficiency (%) 10 VOUT=15V, L=22µH (LQH32CN220K53) 90 65 5 Output Current (mA) VOUT=15V, L=10µH(LQH32CN100K53) Efficiency (%) Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 20 50 0 5 10 15 20 Output Current (mA) 18 R1202x NO.EA-255-210322 VOUT=20V, VIN=3.6V 85 Efficiency (%) 80 75 70 65 LQH32CN100k53L(3.2×2.5×1.55) 60 VLF3010AT-100MR33(3.0×2.8×1.0) 55 LQH2MCN100K02(2.0×1.6×0.9) 50 0 5 10 15 20 Output Current (mA) 2) Efficiency vs. Output Current (R1202N713D) 4LED, L=22µH (LQH32CN220K53) 90 90 85 85 80 80 Efficiency (%) Efficiency (%) 4LED, L=10µH (LQH32CN100K53) 75 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 50 50 0 5 10 15 20 0 15 Output Current ILED (mA) 5LED, L=10µH (LQH32CN100K53) 5LED, L=22µH (LQH32CN220K53) 90 90 85 85 80 80 75 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 50 0 10 5 Output Current ILED (mA) Efficiency (%) Efficiency (%) 75 5 10 15 Output Current ILED (mA) 75 70 65 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 60 55 20 20 50 0 5 10 15 Output Current ILED (mA) 20 19 R1202x NO.EA-255-210322 3) Efficiency vs. Output Current (R1202N713D) 5LED, VIN=3.6V 85 80 Efficiency (%) 75 70 65 60 LQH32CN100k53L(3.2×2.5×1.55) VLF3010AT-100MR33(3.0×2.8×1.0) LQH2MCN100K02(2.0×1.6×0.9) 55 50 0 5 10 15 20 Output Current ILED (mA) 4) Output Voltage vs. Output Current (R1202N723A) VOUT=10V, L=10µH (LQH32CN100K53) 10.8 10.8 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 10.4 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 10.6 Output Voltage (V) 10.6 Output Voltage (V) VOUT=10V, L=22µH (LQH32CN220K53) 10.2 10 9.8 10.4 10.2 10 9.8 9.6 9.6 0 50 100 150 200 0 50 Output Current (mA) VOUT=15V, L=10µH (LQH32CN100K53) 16.4 200 16.4 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 16 Output Voltage (V) Output Voltage (V) 15.6 150 VOUT=15V, L=22µH (LQH32CN220K53) Vin=3V Vin=3.6V Vin=4.2V Vin=5V 16 100 Output Current (mA) 15.2 14.8 14.4 15.6 15.2 14.8 14.4 14 14 0 30 60 Output Current (mA) 90 120 0 30 60 90 120 Output Current (mA) 20 R1202x NO.EA-255-210322 VOUT=20V, L=10µH (LQH32CN100K53) VOUT=20V, L=22µH (LQH32CN220K53) 21.2 21.2 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 20.6 Vin=3V Vin=3.6V Vin=4.2V Vin=5V 20.9 Output Voltage (V) Output Voltage (V) 20.9 20.3 20 19.7 20.6 20.3 20 19.7 19.4 19.4 0 25 50 75 0 100 20 Output Current (mA) 40 60 80 100 Output Current (mA) VOUT=20V, VIN=3.6V 20.5 Output Voltage (V) 20.3 20.1 19.9 LQH32CN100k53L (3.2×2.5×1.55) 19.7 VLF3010AT-100MR33 (2.8×2.6×0.9) LQH2MCN100K02 (2.0×1.6×0.9) 19.5 0 10 20 30 40 50 Output Current (mA) 5) Maxduty vs. ILED 6) OVP Output Waveform R1202N713D 25 25 20 24 Output Voltage (V) ILED (mA) R1202N713D 15 10 200Hz 10kHz 5 300kHz 0 0 20 40 60 Duty (%) 80 100 23 22 21 20 -50 -30 -10 10 Time (ms) 30 50 21 R1202x NO.EA-255-210322 7) Waveform (5LED) R1202N713D (CE Freq=200Hz) R1202N713D (CE Freq=10KHz) 10 5 -5 0 Vout CE -5 0 Time (ms) 5 -5 -500 10 55 5 -5 0 -20 ILED -5 Diode Forward Voltage (V) 10 ILED (mA) 25 10 0 Time [µs] 0.5 -20 -35 500 250 0.90 0.85 0.80 0.75 0.70 0.65 0.60 0.55 0.50 -35 -0.5 0 Time (µs) ILED 0.95 40 15 -1 -250 CE 8) Diode Forward Voltage vs. Temperature 20 CE -5 Vout R1202N713D (CE Freq=300KHz) Vout 10 5 0 -35 -10 25 10 -20 ILED -5 Output Voltage (V) CE Voltage (V) Output Voltage (V) CE Voltage (V) ILED (mA) Output Voltage (V) CE Voltage (V) 25 10 40 15 ILED (mA) 40 15 55 20 55 20 -40 1 -15 10 35 60 85 Temperature Ta (°C) 9) Standby Current vs. Temperature 10) Supply Current lin vs. Temperature 1000 900 Supplay Current Iin[µA] 1.0 Standby Current(uA) 0.8 0.6 0.4 0.2 0.0 800 700 600 500 400 300 200 100 -40 -15 10 35 60 Temperature Ta(°C) 85 0 -40 -15 10 35 60 85 Temperature Ta (°C) 22 R1202x NO.EA-255-210322 11) UVLO Voltage vs. Temperature R1202xxxxA/B R1202xxxxD 2.25 1.75 1.70 2.15 UVLO Voltage(V) UVLO Voltage (V) 2.20 2.10 2.05 2.00 1.95 1.65 1.60 1.55 1.50 1.90 1.85 1.45 -40 -15 10 35 60 85 -40 -15 10 Temperature Ta (°C) 35 60 85 Temperature Ta (°C) 12) VFB Voltage vs. Temperature R1202xxxxD 1.050 0.210 1.030 0.206 0.204 0.208 VFB Voltage (V) VFB Voltage (V) R1202xxxxA/B 1.010 0.990 0.970 0.202 0.200 0.198 0.196 0.194 0.192 0.190 0.950 -40 -15 10 35 Temperature Ta (°C) 60 -40 85 -15 10 35 60 85 Temperature Ta (°C) 13) Switch ON Resistance RON vs. Temperature 14) OVP Voltage vs. Temperature 1.9 25 1.7 24 1.5 OVP Voltage (V) Switch On Resistance RON (Ω) R1202x7xxx 1.3 1.1 0.9 23 22 OVP Detect 21 OVP Release 20 0.7 0.5 -40 -15 10 35 Temperature Ta (°C) 60 85 19 -40 -15 10 35 60 85 Temperature Ta (°C) 23 R1202x NO.EA-255-210322 15) Lx Limit Current vs. Temperature R1202xx1xx R1202xx2xx 900 500 400 Vin=2.8V 850 Vin=3.6V Vin=5.5V Vin=2.8V 800 Vin=3.6V Vin=5.5V Lx Limit Current (mA) Lx Limit Current (mA) 450 350 300 250 750 700 650 600 550 500 200 -40 -15 10 35 -40 85 60 -15 35 60 85 Temperature Ta (°C) Temperature Ta (°C) 16) Frequency Fosc vs. Temperature 17) MaxDuty vs. Temperature 100 1400 Vin=1.8V 1350 98 Vin=3.6V 1300 1250 1200 1150 94 92 90 1100 88 1050 86 1000 -15 -40 10 60 35 Vin=1.8V Vin=3.6V Vin=5.5V 96 Vin=5.5V MXDUTY (%) Frequency Fosc (kHz) 10 85 Temperature Ta (°C) 84 -40 -15 10 35 60 85 Temperature Ta (°C) 18) Thermal Shutdown Detect / Release Temperature vs. Input Voltage 200 Temperature (°C) 180 Thermal Shutdown Detect 160 140 120 Thermal Shutdown Release 100 80 60 1.5 2 2.5 3 3.5 4 VIN (V) 4.5 5 5.5 6 24 R1202x NO.EA-255-210322 19) Inductor Current (output-GND short) 5LED(VIN=3V) R1202N713D 5LED(VIN=3V) R1202N723D 0.5 1 0.45 Inductor Current (A) 0.4 Inductor Current (A) 0.9 IL 0.35 0.3 0.25 0.2 0.15 IL 0.8 0.7 0.6 0.5 0.4 0.3 0.1 0.2 0.05 0.1 0 0 -5 -4 -3 -2 -1 0 1 2 3 4 5 -5 -4 -3 -2 TIme (µs) 1 2 3 4 5 5LED(VIN=3.6V) R1202N723D 0.5 1 0.45 0.9 IL 0.4 0.8 0.35 0.7 Inductor Current (A) Inductor Current (A) 0 TIme (µs) 5LED(VIN=3.6V) R1202N713D 0.3 0.25 0.2 0.15 0.1 0.05 IL 0.6 0.5 0.4 0.3 0.2 0.1 0 -5 -4 -3 -2 -1 0 1 TIme (µs) 2 3 4 5 0 -5 -4 -3 -2 5LED(VIN=4.2V) R1202N713D -1 0 1 TIme (µs) 2 3 4 5 5LED(VIN=4.2V) R1202N723D 0.5 1 0.45 0.9 IL IL 0.8 Inductor Current (A) 0.4 Inductor Current (A) -1 0.35 0.3 0.25 0.2 0.15 0.7 0.6 0.5 0.4 0.3 0.1 0.2 0.05 0.1 0 0 -5 -4 -3 -2 -1 0 1 TIme (µs) 2 3 4 5 -5 -4 -3 -2 -1 0 1 TIme (µs) 2 3 4 5 25 R1202x NO.EA-255-210322 20) Load Transient Response VIN = 3.6 V, VOUT = 15 V IOUT = 0 mA ⇔ 30 mA L = 10 µH Setting：Table 3-A L = 22 µH Setting：Table 3-A L =10 µH Setting：Table 3-B 26 R1202x NO.EA-255-210322 L = 22 µH Setting：Table 3-B 27 POWER DISSIPATION DFN1616-6B Ver. A The power dissipation of the package is dependent on PCB material, layout, and environmental conditions. The following measurement conditions are based on JEDEC STD. 51-7. Measurement Conditions Item Measurement Conditions Environment Mounting on Board (Wind Velocity = 0 m/s) Board Material Glass Cloth Epoxy Plastic (Four-Layer Board) Board Dimensions 76.2 mm × 114.3 mm × 0.8 mm Copper Ratio Outer Layer (First Layer): Less than 95% of 50 mm Square Inner Layers (Second and Third Layers): Approx. 100% of 50 mm Square Outer Layer (Fourth Layer): Approx. 100% of 50 mm Square Through-holes φ 0.2 mm × 15 pcs Measurement Result (Ta = 25°C, Tjmax = 125°C) Item Measurement Result Power Dissipation 2400 mW Thermal Resistance (θja) θja = 41°C/W Thermal Characterization Parameter (ψjt) ψjt = 11°C/W θja: Junction-to-Ambient Thermal Resistance ψjt: Junction-to-Top Thermal Characterization Parameter 3000 2400 Power Dissipation PD (mW) 2500 2000 1500 1000 500 0 0 25 50 75 85 100 125 Ambient Temperature (°C) Power Dissipation vs. Ambient Temperature Measurement Board Pattern i PACKAGE DIMENSIONS DFN1616-6B Ver. A 1.30±0.05 INDEX 4 ∗ 0.4max. 3 0.1±0.05 6 0.25±0.05 0.05 (3X0.15) B 1.60 X4 1.60 0.70±0.05 A 0.5 0.20±0.05 1 0.05 M AB Bottom View S 0.05 S DFN1616-6B Package Dimensions (Unit: mm) * ∗ The tab on the bottom of the package shown by blue circle is a substrate potential (GND). It is recommended that this tab be connected to the ground plane pin on the board but it is possible to leave the tab floating. i POWER DISSIPATION TSOT-23-6 Ver. A The power dissipation of the package is dependent on PCB material, layout, and environmental conditions. The following conditions are used in this measurement. Measurement Conditions Item Standard Test Land Pattern Environment Mounting on Board (Wind Velocity = 0 m/s) Board Material Glass Cloth Epoxy Plastic (Double-Sided Board) Board Dimensions 40 mm × 40 mm × 1.6 mm Top Side: Approx. 50% Copper Ratio Bottom Side: Approx. 50% φ 0.5 mm × 44 pcs Through-holes Measurement Result (Ta = 25°C, Tjmax = 125°C) Item Standard Test Land Pattern Power Dissipation 460 mW Thermal Resistance (θja) θja = 217°C/W Thermal Characterization Parameter (ψjt) ψjt = 40°C/W θja: Junction-to-Ambient Thermal Resistance ψjt: Junction-to-Top Thermal Characterization Parameter 600 Power Dissipation PD (mW) 500 460 400 300 200 100 0 0 25 50 75 85 100 125 Ambient Temperature (°C) Power Dissipation vs. Ambient Temperature Measurement Board Pattern i PACKAGE DIMENSIONS TSOT-23-6 +0.100 0.125-0.025 2.9±0.2 5 4 2 3 +0.10 0.4-0.05 0.85±0.10 0.95 S 0.12 M 0 ∼ 0.1 1 2.8±0.2 +0.2 1.6-0.1 6 0.4±0.2 Ver. A 0.10 S TSOT-23-6 Package Dimensions (Unit: mm) 0∼15° 1. The products and the product specifications described in this document are subject to change or discontinuation of production without notice for reasons such as improvement. Therefore, before deciding to use the products, please refer to Ricoh sales representatives for the latest information thereon. 2. The materials in this document may not be copied or otherwise reproduced in whole or in part without prior written consent of Ricoh. 3. Please be sure to take any necessary formalities under relevant laws or regulations before exporting or otherwise taking out of your country the products or the technical information described herein. 4. The technical information described in this document shows typical characteristics of and example application circuits for the products. The release of such information is not to be construed as a warranty of or a grant of license under Ricoh's or any third party's intellectual property rights or any other rights. 5. 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