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| XC9213 Series Synchronous Step-Down DC/DC Controller IC - Input Voltage : 25V ETR0505_001 GreenOperation Compatible GENERAL DESCRIPTION The XC9213 series is N-ch & N-ch drive, synchronous, step-down DC/DC controller IC with a built-in bootstrap driver circuit. Output will be stable no matter which load capacitors, including low ESR capacitors, are used. Resistance (RSENSE) of about several 10m will be required as a current sense. The phase compensation is also run when a low ESR capacitor is used. In addition, the circuit is double protected by the ways of limiting the current while detecting overshoot current and making output shutdown at any given timing by a protection time setting capacitor (CPRO). The output voltage can be set freely within a range of 1.5V~15.0V with 1.0V (accuracy 2%) of internal reference voltage by using externally connected resistors (RFB1, 2). Synchronous rectification PWM control can be switched to non-synchronous current limit PFM/PWM automatic switchable control (=voltage between RSENSE pins) by using the MODE pin. The series has a built-in voltage detector for monitoring a selected voltage by external resistors. During stand-by (CE pin = low) all circuits are shutdown to reduce current consumption to as low as 4.0 A or less. APPLICATIONS PDAs Mobile phones Note book computers Portable audio systems Various multi-function power supplies FEATURES : 4.0V ~ 25.0V : 1.5V ~ 15.0V externally set Reference voltage: 1.0V ( 2%) Oscillation Frequency : 300kHz ( 15%) Output Current : More than 5A (VIN=5.0V, VOUT=3.3V) Control : PWM/PFM manual-switching control Current Limiter : Current limit operates at voltage Protection sense 170mV (TYP.). Shutdown time can be adjusted by CPRO. High Efficiency : 93% [TYP. PWM Mode@VIN=5.0V, VOUT=3.3V, IOUT=1A] Detect Voltage Function : Detects 0.9V/Open-drain output Stand-by Current : ISTB = 4.0 A (MAX.) Load Capacitor : Low ESR capacitor compatible Synchronous Bootstrap N-ch & N-ch Driver Package : TSSOP-16 Input Voltage Range Output Voltage Range TYPICAL APPLICATION CIRCUIT SD2 TYPICAL PERFORMANCE CHARACTERISTICS RSENSE VIN VDIN VIN CIN VDOUT VDIN VDOUT VL CVL CSS CSS CPRO XC9213 FB EXT2 VSENSE BST EXT1 LX Tr1 CBST L SD1 CFB RFB2 Tr2 RFB1 CL VOUT AGND MODE CE PGND CPRO 1/34 XC9213 Series PIN CONFIGURATION PIN ASSIGNMENT PIN NUMBER 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 PIN NAME VIN VSENSE VL CE AGND MODE CPRO CSS VDIN FB VDOUT PGND EXT2 LX EXT1 BST Input Voltage Current Detection Local Power Supply Chip Enable Analog Ground PWM / Current Limit PFM Switch TSSOP-16 (TOP VIEW) FUNCTION Protection Time Setting Capacitor Connection CE PIN & MODE PIN FUNCTION CE PIN H L MODE PIN H L OPERATIONAL STATE Operation Shut down OPERATIONAL STATE Synchronous PWM Control Non-Synchronous PWM / Current Limit PFM Automatic Switching Control PRODUCT CLASSIFICATION Ordering Information XC9213B DESIGNATOR DESCRIPTION Reference Voltage Oscillation Frequency Package Device Orientation SYMBOL 10 3 V R L : 300kHz : TSSOP-16 : Embossed tape, standard feed : Embossed tape, reverse feed DESCRIPTION : 1.0V (Fixed) 2/34 XC9213 Series ABSOLUTE MAXIMUM RATINGS PARAMETER VIN Pin Voltage VSENSE Pin Voltage VL Pin Voltage CE Pin Voltage (*) MODE Pin Voltage (*) CPRO Pin Voltage CSS Pin Voltage VDIN Pin Voltage FB Pin Voltage VDOUT Pin Voltage EXT2 Pin Voltage Lx Pin Voltage EXT1 Pin Voltage BST Pin Voltage EXT1 Pin Current EXT2 Pin Current Lx Pin Current Power Dissipation Operational Temperature Range Storage Temperature Range SYMBOL VIN VSENSE VL CE MODE CPRO CSS VDIN FB VDOUT EXT2 Lx EXT1 BST IEXT1 IEXT2 ILx Pd Topr Tstg RATINGS - 0.3 ~ 30.0 - 0.3 ~ 30.0 - 0.3 ~ 6.0 - 0.3 ~ 30.0 - 0.3 ~ 30.0 - 0.3 ~ 6.0 - 0.3 ~ 6.0 - 0.3 ~ 6.0 - 0.3 ~ 6.0 - 0.3 ~ 30.0 - 0.3 ~ 6.0 - 0.3 ~ 30.0 - 0.3 ~ 30.0 - 0.3 ~ 30.0 100 100 100 350 - 40 ~ + 85 - 55 ~ + 125 Ta = 25OC UNITS V V V V V V V V V V V V V V mA mA mA mW O C O C (*) CE, MODE pin voltage 1) 1.4V High Level 6V The CE pin and the MODE pin can be connected directly to the high level power supply. 2) 6V < High Level < 30V The CE pin and the MODE pin should be connected to over 1k resistor when connecting 1.4V IC Inside CE or MODE IC Inside CE or MODE 3/34 XC9213 Series ELECTRICAL CHARACTERISTICS XC9213B103 (FOSC = 300kHz) PARAMETER Input Voltage (*2) Output Voltage Setting Range FB Control Voltage U.V.L.O. Voltage Supply Current 1 Supply Current 2 Stand-by Current Oscillation Frequency Maximum Duty Ratio 1 Maximum Duty Ratio 2 PFM Duty Ratio Sense Voltage CPRO time Soft-Start Time Short Protection Circuit Operating Voltage Efficiency CE "H" Voltage CE "L" Voltage MODE "H" Voltage MODE "L" Voltage EXT1 "H" ON Resistance EXT1 "L" ON Resistance EXT2 "H" ON Resistance EXT2 "L" ON Resistance Dead Time 1 Dead Time 2 CE "H" Current CE "L" Current MODE "H" Current MODE "L" Current CSS Current FB "H" Current FB "L" Current SYMBOL VIN VOUTSET VFB UVLO IDD1 IDD2 ISTB FOSC MAXDTY1 MAXDTY2 PFMDTY VSENSE TPRO TSS VSHORT EFFI VCEH VCEL VMODEH VMODEL REXT1H REXT1L REXT2H REXT2L TDT1 TDT2 ICEH ICEL IMODEH IMODEL ICSS IFBH IFBL Voltage which EXT1 pin starts oscillation CE=VIN, FB=0.9V CE=VIN, FB=1.1V CE=FB=0V CE=VIN, FB=0.9V CE=VIN, FB=0.9V CE=VIN, FB=1.1V With external components, VOUT=3V, MODE=0V, IOUT=1mA, No RSENSE Voltage which EXT1 pin stops oscillation CPRO=4700pF, VSENSE=0V 0.5V, Time until VDOUT inverts H to L With external components, CSS=4700pF, CE=0V 3V, Time until voltage becomes VOUT x 0.95 VIN-VSENSE: 0.3V fixed, FB: SWEEP. Voltage which VDOUT inverts H to L With external components, IOUT=1A, VOUT=3.0V Voltage which EXT1 pin starts oscillation Voltage which EXT1 pin voltage holding "L" level Voltage which EXT2 pin starts oscillation Voltage which EXT2 pin voltage holding "L" level FB=0.9V, EXT1=3.6V FB=1.1V, EXT1=0.4V FB=1.1V, EXT1=3.6V FB=0.9V, EXT2=0.4V With external components, EXT1: H L, EXT2: L H With external components, EXT2: H L, EXT1: L H CE=5.0V CE=0V MODE=5.0V MODE=0V CSS=0V FB=5.0V FB=0V CONDITIONS MIN. 4.0 1.5 0.980 1.0 255 91 2.5 145 2.3 4 0.15 1.4 1.4 -0.1 -0.1 -4.0 -0.1 TYP. 1.000 1.5 550 450 300 95 98 3.0 170 4.7 8 0.40 93 18 11 18 4 100 60 -2.0 MAX. 25.0 15.0 1.020 2.0 800 600 4.0 345 3.9 200 9.4 21 0.72 0.4 0.4 23 18 23 8 0.1 0.1 0.1 ns ns A A A A A A A UNITS V V V V A A A kHz % % s mV ms ms V % V V V V Ta=25OC CIRCUIT 1 2 3 3 4 5 5 5 6 7 8 9 25 10 11 11 12 12 13 14 15 16 10 10 17 17 18 18 19 20 20 4/34 XC9213 Series ELECTRICAL CHARACTERISTICS (Continued) XC9213B103 (Continued) Voltage Regulator (*3) PARAMETER Output Voltage Load Regulation Input Regulation SYMBOL VLOUT VLOUT VLOUT VINVLOUT CONDITIONS FB=1.1V, ILOUT=10mA FB=1.1V, 1mAILOUT30mA FB=1.1V, ILOUT=10mA, VLOUT+1VVIN25V MIN. 3.86 TYP. 4.00 45 0.05 MAX. 4.14 90 0.1 UNITS CIRCUIT V mV %/V 21 21 21 Voltage Detector PARAMETER Detect Voltage Release Voltage (*4) Hysteresis Range Output Current Delay Time VDIN Current NOTE: *1: Unless otherwise stated, VIN=5.0V, CE=5.0V, MODE=5.0V, FB=0.9V *2: The operation may not be stable at no load, if the step-down ratio (VOUT/VIN x 100) becomes lower than 12%. *3: The regulator block is used only for bootstrap. *4: Release voltage: (VDR) = VDF + HYS x VDF Please do not use as a local power supply. SYMBOL VDF VDR HYS VDIOUT TDLY IVDIN CONDITIONS FB=1.1V, Voltage which VDOUT inverters H to L FB=1.1V, Voltage which VDOUT inverters L to H FB=1.1V FB=1.1V, VDIN=VDF-0.4V, VDOUT=0.5V VDRVDOUT inversion VDIN=5.0V MIN. 0.855 0.915 2.9 5 - TYP. 0.900 0.954 6.0 15 - MAX. 0.925 0.980 7.5 20 10 0.1 UNITS CIRCUIT V V % mA s A 22 22 22 23 22 24 5/34 XC9213 Series TEST CIRCUITS Circuit 1 Circuit 2 OCS OCS Circuit 3 Circuit 4 Circuit 5 Circuit 6 SBD1 OSC OSC CIN BST EXT1 LX EXT2 PGND CFB VDOUT FB VDIN RFB2 Tr2 RFB1 VIN VSE NSE VL CE + 10u F 1uF AGND MODE + + 100p F CPRO CSS BST EXT1 LX EXT2 PGND VDOUT FB VDIN 100pF VIN OCS OCS 100 k 100 k 1uF Tr1 L VSENSE VL CE + 1uF + AGND MODE + CPRO CSS OCS OCS CL + - Circuit 7 Tr1: Tr2: SBD1: L: 22 H CL: 100 F CIN1: 22 F RFB1: 220k RFB2: 110k CFB: 68pF 2SK2857 (NEC) 2SK2857 (NEC) CRS02 (TOSHIBA) CDRH6D28 (SUMIDA) (OS-CON, NIPPON CHEMI-CON) (OS-CON, SANYO) + - VIN VSENSE VL CE BST EXT1 LX EXT2 PGND VDOUT FB VDIN + - OSC OSC 100k 100k + - 10uF 1uF AGND MODE + + 100pF 100pF CPRO CSS 6/34 XC9213 Series TEST CIRCUITS (Continued) Circuit 8 Circuit 9 VIN RSENSE: 33 m + VIN VSE NSE VL CE + 10uF 1uF AGND M O DE + + CPR CSS BST EXT1 LX EXT2 PG ND VDO UT FB VDIN + - XB01SB04A2BR(TOREX) OSC OSC 100k 100k VIN VSENSE VL ceramic 1uF CE AGND MODE CPRO CSS ceramic 4700pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN ceramic 10uF+10uF ceramic 1uF IRF7313 (IR) 7.4uH(SUMIDA) VOUT CMS02 (TOSHIBA) VIN 100k VL 100k 100k ceramic 47pF 200k 4700pF 100pF GND Circuit 10 Circuit 11 VIN RSENSE: 33 m XB01SB04A2BR(TOREX) VIN VSE NSE VL ceramic 1uF CE AGND MODE CPRO ceramic 4700pF CSS ceramic 4700pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN VL 100k 100k CMS02 (TOSHIBA) VIN 100k ceramic 10uF+10uF ceramic 1uF IRF7313 (IR) 7.4uH(SUMIDA) + (NIPP ON CH EMI-CON) VIN VSENSE VL CE 10uF 1uF AGND MODE + CPRO CSS 100pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN + - 25PS100JM12 100uF (NIPPON CHEMI-CON) OSC OSC 100k 100k ceramic 47pF 200k 25 PS 100 JM12 100u F GND Circuit 12 Circuit 13 VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS 100pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN + 100k 100k VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS 100pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN + - OSC OSC OSC OSC 50k + 10uF 7/34 XC9213 Series TEST CIRCUITS (Continued) Circuit 14 Circuit 15 VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS 100pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN + V VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS 100pF BST EXT1 LX EXT2 PGND VDOUT FB VDIN + + 10uF 50 OSC OSC Circuit 16 Circuit 17 VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS BST EXT1 LX EXT2 PGND VDOUT FB VDIN + V VIN VSENSE VL CE + 10uF 1uF A AGND MODE + CPRO CSS BST EXT1 LX EXT2 PGND VDOUT FB VDIN 100k 100k 100pF 100pF Circuit 18 Circuit 19 VIN VSENSE VL CE + 10uF 1uF AGND MODE A + CPRO CSS VIN BST EXT1 LX EXT2 PGND VDOUT FB VDIN 100k 100k BST EXT1 LX EXT2 PGND VDOUT FB VDIN 100k 100k VSENSE VL CE + 10uF 1uF AGND MODE + + CPRO CSS A 100pF 8/34 XC9213 Series TEST CIRCUITS (Continued) Circuit 20 Circuit 21 VIN VSENSE VL CE + 10uF 1uF AGND MODE CPRO CSS 100p F BST EXT1 LX EXT2 PGND VDOUT FB VDIN A + 100k 100k VIN VSE NSE VL IL CE 1uF V AGND MODE + + CPRO CSS BST EXT1 LX EXT2 PGND VDOUT FB VDIN + 100 k 100 k + - 10u F 100p F Circuit 22 Circuit 23 VIN VSENSE VL CE + 10uF 1uF AGND MODE + CPRO CSS BST EXT1 LX EXT2 PGND VDOUT FB VDIN + - VIN 100k BST EXT1 LX EXT2 PGND VDOUT FB VDIN + + + A VSE NSE VL CE + V 10u F 1uF AGND MODE + CPRO CSS 100p F + - 100p F Circuit 24 Circuit 25 VIN VSE NSE VL CE FF + 10u 1u AGND MODE CPRO CSS 100p F BST EXT1 LX EXT2 PGND VDOUT FB VDIN 100 k + - VIN VSENSE VL CE BST EXT1 LX EXT2 PGND VDOUT FB VDIN + - OSC OSC 100k 100k + - 10uF 1uF AGND MODE + + CPRO CSS 100pF A + - 9/34 XC9213 Series BLOCK DIAGRAM OPERATIONAL EXPLANATION < Error Amplifier > The error amplifier is designed to monitor output voltage. The amplifier compares the reference voltage with the feedback voltage. When a voltage lower than the reference voltage is fed back, the output voltage of the error amplifier increases. 10/34 XC9213 Series OPERATIONAL EXPLANATION (Continued) < Protection Circuit Operation (Current Limit, Latch Protection Circuit, and Short Protection Circuit) > Shown above is a timing chart for protection circuit operations. When the output current changes from normal to an overcurrent condition, the current-limiting circuit detects the overcurrent condition as a voltage drop occurring, by virtue of the current-sensing resistor, at the VSENSE pin. Upon detection, the current-limiting circuit limits the peak current passed through the high-side N-ch MOSFET at every clock pulse (state ). It is possible to regulate the value of limited current by varying the resistance value of the current-sensing resistor. A protection circuit (protective latch circuit), which is designed to stop the clock, functions if the overcurrent condition continues for a predetermined time (state ). Time delay before the protective latch circuit functions is adjustable by the capacitance connected to the CPRO pin (typically 4.7 ms if CPRO has 4,700 pF). The protective latch circuit is reset by turning off and on, or by a disable action followed by an enable action using the CE pin. If, furthermore, the output is short-circuited (state ) and VOUT decreases to a value close to 0 V, the short-circuit protection circuit detects the condition by means of the FB pin and stops the clock with no time delay. The short-circuit protection circuit is reset by turning off and on or by a disable action followed by an enable action using the CE pin, as with the protective latch circuit. < Mode Control Logic > A timing chart for automatic switching of current-limiting PFM/PWM is shown above. High-level of the MODE pin allows PWM operations to occur for synchronous rectification (state ). When the MODE pin shifts to low-level, current-limiting PFM/PWM automatic switching occurs with synchronous rectification stopped. Consequently, the low-side N-ch MOSFET is constantly off under this condition. In addition, a comparison is made for the purposes of automatic switching, between the ON time of the high-side N-ch MOSFET determined by the internal error amp. and the time required for the current passed at every clock pulse through the high-side N-ch MOSFET to reach a preset amount of current. The longer one is selected and becomes on duty (state or ). If the time determined by the error amp. is longer than the other, PWM operation occurs. Current-limiting PFM operation occurs if the time taken by the current passing at every clock pulse to reach a preset amount of current is longer. Thus the automatic switching mechanism achieves high efficiency under light to heavy load conditions. 11/34 XC9213 Series TYPICAL APPLICATION CIRCUIT *Please place CIN close to RSENSE as much as possible, so that an impedance does not occur between the elements. *Please place CIN, RSENSE, Tr1, Tr2, L, CL, and SD1 as close as possible to each other. EXTERNAL COMPONENTS * Please refer to the DC/DC simulation section of the Torex web site (http//:www.torex.co.jp) for more details. Recommended N-ch MOSFETs for Tr1 and Tr2 IOUT: Less than 3A PART NUMBER uPA2751GR IRF7313 IOUT: More than 3A PART NUMBER SUD30N03 SUD70N03 MANUFACTURER Vishay Vishay TYPE Single Single Ciss (pF) 1170 2700 Crss (pF) 30 360 Crss / (Ciss + Crss) 0.049 0.118 MANUFACTURER NEC International Rectifier TYPE Dual Dual Ciss (pF) 1040 650 Crss (pF) 130 130 Crss / (Ciss + Crss) 0.111 0.167 * It is recommended to use MOSFETs with Ciss less than 3000pF. * For Tr2, MOSFETs with smaller Crss / (Ciss + Crss) are recommended. Recommended Coil (L) PART NUMBER CDRH127/LD-7R4 CDRH127-6R1 MANUFACTURER SUMIDA SUMIDA H. * For stable operation, please use a coil with L less than 22 Recommended Capacitor (CIN, CVL, CBST, CL) COMPONENTS CIN (*1) CVL CBST CL (*2) PART NUMBER 25SC22M 20SS150M 25PS100JM12 MANUFACTURER SANYO SANYO NIPPON CHEMI-CON TYPE Ceramic OS Ceramic Ceramic OS VALUE 10 F 22 F 1F 1 F ~ 4.7 F 150 F 100 F PCS 2 1 1 1 1 (*1)Please place CIN close to RSENSE as much as possible, so that an impedance does not occur between the elements. A 1F ceramic capacitor is recommended for CVL. (*2)Operation may become unstable if a ceramic capacitor is used for CL. 12/34 XC9213 Series EXTERNAL COMPONENTS (Continued) Output Voltage Setting (RFB1, RFB2, CFB) Output voltage can be set by adding external split resistors. Output voltage is determined by the following equation, based on the values of RFB1 and RFB2. The sum of RFB1 and RFB2 should normally be 2 M or less (RFB1 + RFB2 2M ). VOUT = RFB1 / RFB2 + 1 The value of CFB, speed-up capacitor for phase compensation, should be adjusted by the following equation. fzfb= 1 / (2 x capacity (CL). VOUT (V) 1.5 1.8 2.5 3.0 3.3 5.0 RFB1 ( 150 160 360 220 620 300 ) RFB2 ( 300 200 240 110 270 75 ) CFB (pF) 100 100 47 47 27 47 x CFB x RFB1) 10kHz Adjustments are required from 1kHz to 50kHz depending on the application, value of inductance (L), and value of load Recommended Schottky Diode (SD1, SD2) SYMBOL SD1 SD2 PART NUMBER CMS02 DE5PC3 XB01SB04A2BR CRS02 MANUFACTURER TOSHIBA SHINDENGEN TOREX TOSHIBA If, in particular, SD2 has poor reverse-current characteristics, * SD1 and SD2 should be of favorable reverse-current characteristics. CBST cannot be fully charged at high temperatures, resulting, in some cases, in failure to drive Tr1. Setting Latch Protection Circuit Delay Time (CPRO) Time delay is 4.7 ms (TYP.) under the current conditions if CPRO has 4,700 pF. This time delay is roughly proportional to the value of CPRO. ex.) When CPRO is 2200pF, When CPRO is 0.01 F (10,000pF), 4.7ms (TYP.) x 2200pF / 4700pF 4.7ms (TYP.) x 10000pF / 4700pF =2.2ms (TYP.) =10ms (TYP.) * For stable operation, please use a capacitor with more than 2200pF as CPRO. Setting Soft-Start Time (CSS) Relationships between the value of CSS and the soft-start time (25OC TYP.) are shown at left. For stable operation, please use a capacitor with more than 2200pF as CSS. 13/34 XC9213 Series EXTERNAL COMPONENTS (Continued) Sense Resistance (RSENSE) The below values can be adjusted by using sense resistance (RSENSE). It is recommended using the RSENSE value in the range of 20m to 100m. 1) Detect current value of the overcurrent detect circuit Maximum output current (IOUTMAX) can be adjusted as the equation below. IOUTMAX (A) 200mV (MAX.) / RSENSE (m ) When 4V VIN 5V, the maximum output current becomes larger than the calculated value. Please also refer to the characteristics performance below. 2) Peak current value of the current limit PFM control Peak current value of the current limit PFM control (I_PFM) varies depending on the dropout voltage (VDIF), the coil (L) value and the sense resistance value (RSENSE). For the XC9213 series' sample with voltage sense (VSENSE) 170mV, the characteristic performance below shows the changes in the peak current (I_PFM) when the sense resistance values (RSENSE) are 20m , 33 m , and 50 m . The peak current varies according to the dropout voltage and the coil value. PFM Peak Current 3.0 I_PFM(TYP. 25 ) (A) 2.5 2.0 1.5 1.0 0.5 0.0 0 1 2 Vdif/L (V/ 3 H) 4 5 RSENSE:20m I_PFM(TYP. 25 ) (A) 3.0 2.5 2.0 1.5 1.0 0.5 0.0 0 1 2 Vdif/L (V/ 3 H) 4 5 PFM Peak Current RSENSE:33m PFM Peak Current 3.0 I_PFM(TYP. 25 ) (A) 2.5 2.0 1.5 1.0 0.5 0.0 0 1 2 Vdif/L (V/ 3 H) 4 5 RSENSE:50m The sense voltage varies within the range of 145 mV The peak current as shown in three graphs fluctuates according to the sample's sense voltage. VSENSE 200mV. 14/34 XC9213 Series EXTERNAL COMPONENTS (Continued) Divided Resistors For VD Input Voltages (RVDIN1, RVDIN2) Detect voltage of the detector block can be adjusted by the external divided resistors for VD input voltages (RVDIN1, RVDIN2) as the equation below. When 0.855V < VDF < 0.925V (0.9V TYP.) Detect voltage = VDF x (RVDIN1 + RVDIN2) / RVDIN2 [V] Please select RVDIN1 and RVDIN2 as the sum of RVDIN1 and RVDIN2 becomes less than 2M. Divided Resistor For VD Output Voltage (RVDOUT) Output type of the detector block is N-channel open drain. Please use a 1k resistor or more as RVDOUT. APPLICATION CIRCUIT EXAMPLE The application circuit shown below is the example for using the detector block as power good. Please connect the VDIN pin with the FB pin as below. 15/34 XC9213 Series NOTES ON USE 1. Overcurrent Limit Function The internal current detection circuit is designed to monitor voltage occurs between RSENSE resistors in the overcurrent condition. In case that the overcurrent limit function operates when the output is shorted, etc., the current detection circuit detects that the voltage between RSENSE resistors reaches the SENSE voltage (170mV TYP.), and, thereby, the overcurrent limit circuit outputs the signal, which makes High side's N-ch MOSFET turn off. Therefore, delay time will occur (300ns TYP.) after the current detection circuit detects the SENSE voltage before High side's N-ch MOSFET turns off. When the overcurrent limit function operates because of rapid load fluctuation etc., the SENSE voltage will spread during the delay time without being limited at the voltage value, which is supposed to be limited. Therefore, please be noted to the absolute maximum ratings of external MOSFET, a coil, and an Schottky diode. 2. Short Protection Circuit In case that a power supply is applied to the IC while the output is shorted, or the IC is switched to enable state from disable state via the CE pin, when High side's N-ch MOSFET is ON and Low side's N-ch MOSFET is OFF, the potential difference for input voltage will occur to the both ends of a coil. Therefore, the time rate of coil current becomes large. By contrast, when High side's N-ch MOSFET is OFF and Low side's N-ch MOSFET is ON, there is almost no potential difference at both ends of the coil since the output voltage is shorted to the Ground. For this, the time rate of coil current becomes quite small. This operation is repeated within soft-start time; therefore, coil current will increase for every clock. Also with the delay time of the circuit, coil current will be converged on a certain current value without being limited at the current amount, which is supposed to be limited. However, step-down operation will stop and the circuit can be latched if FB voltage is decreasing to the voltage level, which enables to operate a short protection circuit when the soft-start time completes. Even if the FB voltage is not decreasing to the voltage level, which a short protection circuit cannot be operated, the step-down operation stops when CPRO time completes, and the circuit will be latched. Please be noted to the absolute maximum ratings of external MOSFET, a coil, and an Schottky diode. 3. Current Limit PFM Control With a built-in bootstrap buffer driver circuit, the XC9213 series generates voltage for Tr1 to be turned on by charging CBST with VL (4V). When Tr1 is off, Tr2 is on, and the Lx signal is low, it will be suitable timing for charging CBST. (Please refer to the above figure.) For that reason, at PFM control (MODE: Low), the clock pulses will decrease extremely according to the decrease of the load current. As a result, it will cause a decrease of charging frequency and an electric discharge of CBST so that sufficient voltage for the Tr1 to be turned on will not be supplied. Therefore, 1) Please use a Schottky Barrier Diode with few reverse current values for SD2. 2) Please avoid extreme light loads (e.g. less than a few mA) Moreover, the above-mentioned operation may occur, influenced by external components including SD2 and ambient temperature. It's recommended to use the IC after evaluation with an actual device. VL(4V) SD2 BST VIN Tr1 EXT1 CBST XC9213 LX L GND CL CBST Charge CBST Charge Tr2 EXT2 SD1 LX W aveform (MODE:Low, PFM) PGND 16/34 XC9213 Series NOTES ON USE (Continued) 4. Switching on and off the IC by the input voltage pin When the IC is switched on and off by the input voltage pin (VIN) instead of the chip enable pin (CE), the IC may stop operation because a protection circuit built inside the short-protection circuit, etc. begins to work in order to block ON signal which is sent before the soft-start capacitor connection pin (CSS) resets. The following methods can be used for avoiding this situation; a) Turn on the power source again after input voltage becomes below U.V.L.O. detect voltage (1.0V MIN.), furthermore, after the lapse of the time constant of =CSS x 50k. b) Before turning the power source on again, start-up the IC after resetting the CSS forcibly and keeping soft-start time. Please make sure the CSS pin is discharged once and the soft-start time is secured when starting up the IC. 17/34 XC9213 Series REFERENCE PCB LAYOUT Layout For Using a Dual MOSFET TOREX VDOUT SD2 VIN CIN + RSENSE CE RVD3 CBST RSENSE SD 0306 TR CVL MODE CDD RVD2 CPRO CSS GND VER.2.0B IC CL CL SD1 Resistance SD Tr Ceramic Capacitor Test pin VDIN + RFB1 CFB VL VOUT RFB2 FB L L Layout For Using a Single MOSFET RSENSE 0308 VER.2.1A G G SD TR1 RSENSE XC9213 VIN CIN Tr CIN TOREX + XC9213 RVD1 VDOUT SD2 Resistance RVD3 CBST TR2 Ceramic Capacitor MODE CPRO GND SD1 CSS SD CDD CVL CE IC Test pin L VL RVD1 RVD2 CL + RFB2 VDIN RFB1 FB CFB CL CL + VOUT L Tr * Please use tinned wires etc. for the VIN, the VOUT, and the GND. ** Please attach test pins etc. to the CE, the MODE, the EXT, and the EXT2. *** Please solder mount the RSENSE and the CE as close as possible. 18/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Unless otherwise stated, Topr:25 ) (1) Output Voltage vs. Output Current VOUT vs. IOUT 2.0 VOUT vs. IOUT FET:IRF7313 2.0 FET:SUD30N03 Output Voltage VOUT (mA) 1.8 VIN:5V, 8V, 15V, 20V Output Voltage VOUT (mA) 1.9 1.9 1.8 VIN:5V, 8V, 15V, 20V 1.7 1.7 1.6 1.6 1.5 10 100 1000 Output Current IOUT (mA) 10000 1.5 10 100 1000 Output Current IOUT (mA) 10000 VOUT vs. IOUT 3.5 FET:IRF7313 3.5 VOUT vs. IOUT FET:SUD30N03 Output Voltage VOUT (mA) 3.3 VIN:5V, 8V, 15V, 20V Output Voltage VOUT (mA) 3.4 3.4 3.3 VIN:5V, 8V, 15V, 20V 3.2 3.2 3.1 3.1 3.0 10 100 1000 Output Current IOUT (mA) 10000 3.0 10 100 1000 Output Current IOUT (mA) 10000 VOUT vs. IOUT 5.2 FET:IRF7313 VOUT vs. IOUT 5.2 FET:SUD30N03 Output Voltage VOUT (mA) Output Voltage VOUT (mA) 5.1 5.1 5.0 5.0 VIN:8V, 15V, 20V 4.9 VIN:8V, 15V, 20V 4.9 4.8 4.8 4.7 10 100 1000 Output Current IOUT (mA) 10000 4.7 10 100 1000 Output Current IOUT (mA) 10000 19/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (2) Output Voltage vs. Output Current VOUT vs. IOUT 2.0 FET:IRF7313 2.0 VOUT vs. IOUT FET:SUD30N03 Output Voltage VOUT (mA) 1.8 VIN:5V, 8V, 15V, 20V Output Voltage VOUT (mA) 1.9 1.9 1.8 VIN:5V, 8V, 15V, 20V 1.7 1.7 1.6 1.6 1.5 10 100 1000 Output Current IOUT (mA) 10000 1.5 10 100 1000 Output Current IOUT (mA) 10000 VOUT vs. IOUT 3.5 FET:IRF7313 VOUT vs. IOUT 3.5 FET:SUD30N03 Output Voltage VOUT (mA) Output Voltage VOUT (mA) 3.4 3.4 3.3 VIN:5V, 8V, 15V, 20V 3.3 VIN:5V, 8V, 15V, 20V 3.2 3.2 3.1 3.1 3.0 10 100 1000 Output Current IOUT (mA) 10000 3.0 10 100 1000 Output Current IOUT (mA) 10000 VOUT vs. IOUT 5.2 FET:IRF7313 5.2 VOUT vs. IOUT FET:SUD30N03 Output Voltage VOUT (mA) Output Voltage VOUT (mA) 5.1 5.1 5.0 VIN:8V, 15V, 20V 5.0 VIN:8V, 15V, 20V 4.9 4.9 4.8 4.8 4.7 10 100 1000 Output Current IOUT (mA) 10000 4.7 10 100 1000 Output Current IOUT (mA) 10000 20/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (3) Efficiency vs. Output Current EFFI. vs. IOUT VOUT:1.8V, FET:IRF7313 EFFI. vs. IOUT VOUT:1.8V, FET:SUD30N03 100 100 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 40 VIN:5V, 8V, 15V, 20V 20 40 VIN:5V, 8V, 15V, 20V 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 100 EFFI vs. IOUT VOUT:3.3V, FET:IRF7313 100 EFFI. vs. IOUT VOUT:3.3V, FET:SUD30N03 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 40 VIN:5V, 8V, 15V, 20V 20 40 VIN:5V, 8V, 15V, 20V 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 100 EFFI. vs. IOUT VOUT:5.0V, FET:IRF7313 100 EFFI. vs. IOUT VOUT:5.0V, FET:SUD30N03 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 40 VIN:8V, 15V, 20V 20 40 VIN:8V, 15V, 20V 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 21/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (4) Efficiency vs. Output Current EFFI. vs. IOUT 100 VOUT:1.8V, FET:IRF7313 100 EFFI. vs. IOUT VOUT:1.8V, FET:SUD30N03 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 VIN:5V, 8V, 15V, 20V 40 VIN:5V, 8V, 15V, 20V 40 20 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 100 EFFI. vs. IOUT VOUT:3.3V, FET:IRF7313 EFFI. vs. IOUT 100 VOUT:3.3V, FET:SUD30N03 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 40 VIN:5V, 8V, 15V, 20V 20 40 VIN:5V, 8V, 15V, 20V 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 EFFI. vs. IOUT 100 VOUT:5.0V, FET:IRF7313 100 EFFI. vs. IOUT VOUT:5.0V, FET:SUD30N03 80 Efficiency EFFI. (%) Efficiency EFFI. (%) 80 60 60 40 VIN:8V, 15V, 20V 20 40 VIN:8V, 15V, 20V 20 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 22/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (5) Ripple Voltage vs. Output Current Vripple vs. IOUT 80 FET:IRF7313, VIN=5V, VOUT=3.3V 80 Vripple vs. IOUT FET:SUD30N03, VIN=5V, VOUT=3.3V Ripple Voltage Vripple (mV) Ripple Voltage Vripple (mV) 60 CL:150 40 CL:300 20 F (OS-CON SANYO) F (OS-CON SANYO) 60 CL:150 40 CL:300 20 F (OS-CON SANYO) F (OS-CON SANYO) 0 10 100 1000 Output Current IOUT (mA) 10000 0 10 100 1000 Output Current IOUT (mA) 10000 Vripple vs. IOUT 80 FET:IRF7313, VIN=15V, VOUT=5.0V 80 Vripple vs. IOUT FET:SUD30N03, VIN=15V, VOUT=5.0V Ripple Voltage Vripple (mV) 60 Ripple Voltage Vripple (mV) CL:150 F (OS-CON SANYO) 60 CL:150 F (OS-CON SANYO) 40 40 20 CL:300 0 10 100 1000 Output Current IOUT (mA) 10000 F (OS-CON SANYO) 20 CL:300 F (OS-CON SANYO) 0 10 100 1000 Output Current IOUT (mA) 10000 (6) FB Voltage Temperature Characteristics VFB vs. Topr 1.04 -based) 100 VFB Temperature coefficient vs. Topr (25 -based) VFB Temperature coefficient (ppm/ ,25 1.02 FB Voltage(V) (V) VFB VFB 50 1.00 0 0.98 0.96 -50 0.94 -50 0 -100 -50 0 Temperature Topr( Topr ( ) 50 100 ) Temperature Topr( Topr ( ) 50 100 ) 23/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (7) Oscillation Frequency Temperature Characteristics FOSC vs. Topr 400 -based) 3000 2000 1000 0 -1000 -2000 -3000 -50 0 Topr ( ) Temperature Topr( 50 100 FOSC Temperature Coefficient vs. Topr (25 -based) 350 FOSC kHz 300 250 200 -50 Topr ( ) Temperature Topr( 0 50 100 FOSC Temperature coefficient (ppm/ ,25 ) ) (8) Supply Current 1 & 2 Temperature Characteristics IDD1 vs. Topr 800 700 Supply Current 2 IDD2 (A) 600 500 400 300 200 -50 800 700 600 500 400 300 200 -50 IDD2 vs. Topr Supply Current 1 IDD1 ( A) 0 50 100 0 50 100 Topr ( ) Temperature Topr( ) Temperature Topr( Topr ( ) ) (9) Stand-by Current Temperature Characteristics ISTB vs. Topr 10 Standby Current ISTB ( A) 8 6 4 2 0 -50 0 50 100 Topr ) Temperature(Topr( ) 24/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (10) VR Output Voltage Temperature Characteristics -based) VLOUT vs. Topr 4.2 VLOUT Temperature coefficient vs. Topr (25 100 -based) VD Output Volage VLOUT (V) 4.1 ,25 VLOUT Temperature coefficient (ppm/ -50 0 50 100 50 4.0 0 3.9 -50 3.8 -100 -50 0 50 100 Temperature( Topr( ) Topr ) Temperature Topr( Topr ( ) ) (11) VD Detect Voltage Temperature Characteristics VDF vs. Topr 1.00 (12) VD Release Voltage Temperature Characteristics VDR vs. Topr 1.00 Detect Voltage VDF (V) 0.90 Release Voltage VDR (V) -50 0 50 Topr ( ) 100 0.95 0.95 0.90 0.85 0.85 0.80 0.80 -50 0 Topr ( ) Temperature Topr( 50 100 Temperature Topr( ) ) (13) CE "H", "L" Voltage Temperature Characteristics VCEH vs. Topr 1.4 1.2 CE "H" Voltage VCEH (V) 1.0 0.8 0.6 0.4 0.2 -50 0 50 100 CE "L" Voltage VCEL (V) 1.4 1.2 1.0 0.8 0.6 0.4 0.2 -50 0 50 100 VCEL vs. Topr Temperature Topr( Topr ( ) ) Temperature Topr( Topr ( ) ) 25/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (14) MODE "H", "L" Voltage Temperature Characteristics VMODEH vs. Topr 1.4 1.2 1.0 0.8 0.6 0.4 0.2 -50 0 50 100 VMODEL vs. Topr 1.4 1.2 1.0 0.8 0.6 0.4 0.2 -50 0 50 100 MODE "H" Voltage VMODEH V Temperature Topr( Topr ( ) ) MODE "L" Voltage VMODEL V Temperature Topr( Topr ( ) ) (15) Sense Voltage Temperature Characteristics VSENSE vs. Topr 0.20 (16) Short Protection Circuit Operation Voltage Temperature Characteristics VSHORT vs. Topr Short Protection Circuit Operating Voltage VSHORT (V) VIN:5V, VOUT:1.8V, RSENSE:33m , L:6.1 H 0.7 0.6 0.5 0.4 0.3 0.2 0.1 -50 0 50 100 Topr ( ) Temperature Topr( Sense Voltage VSENSE (V) 0.18 0.16 0.14 0.12 0.10 -50 0 50 100 Temperature Topr( Topr ( ) ) ) (17) U.V.L.O. Voltage Temperature Characteristics UVLO vs. Topr 2.5 U.V.L.O. Voltage UVLO (V) 2.0 1.5 1.0 0.5 -50 0 Topr ( Topr( Temperature ) 50 100 ) 26/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (18) Load Transient Response Characteristics MODE: High FET:IRF7313 (International Rectifier) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) MODE: High FET:IRF7313 (International Rectifier) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) 27/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (18) Load Transient Response Characteristics MODE: High FET: SUD30N03 (Vishay) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) MODE: High FET: SUD30N03 (Vishay) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) 28/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (18) Load Transient Response Characteristics MODE: High FET:SUD30N03 (Vishay) RSENSE:33m CL:150 F (OS-CON, SANYO) L:CDRH127/LD-7R4 (SUMIDA) MODE: High FET: SUD30N03 (Vishay) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) 29/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (19) Load Transient Response Characteristics MODE: Low FET: SUD30N03 (Vishay) RSENSE:33m CL:150 F (OS-CON, SANYO) L: CDRH127/LD-7R4 (SUMIDA) 30/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (20) Latch Protection Circuit Operating Waveform Topr : 85 31/34 XC9213 Series TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (21) Short-circuit Protection Circuit Operation Waveform Topr : 85 (22) Soft-start Circuit Operation Waveform 32/34 XC9213 Series PACKAGING INFORMATION TSSOP-16 0. 22 +0. 1 - 0. 05 4. 4 0. 2 5. 1 0. 2 1. 15 0. 1 0. 22 +0. 1 - 0. 05 0. 65 MARKING RULE TSSOP-16 16 15 14 13 12 11 10 9 Represents product series MARK 2 1 3 B PRODUCT SERIES XC9213B103Vx abc d Represents standard voltage MARK 1 0 VOLTAGE (V) 1.0 PRODUCT SERIES XC9213B103Vx 1 2 3 4 5 6 7 8 Represents oscillation frequency MARK 3 OSCILLATION FREQUENCY 300kHz PRODUCT SERIES XC9213B103Vx TSSOP-16 (TOP VIEW) 0. 1 0. 05 6. 4 0. 2 0. 5 0. 2 33/34 XC9213 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. 34/34 |
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