S-8333ACGA-T8T1G

Rev.2.3_00 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER S-8333 Series The S-8333 Series is a CMOS step-up switching regulator which mainly consists of a reference voltage circuit, an oscillator, an error amplifier, a PWM controller, an under voltage lockout circuit (UVLO), and a timer latch short-circuit protection circuit. Because its minimum operating voltage is as low as 1.8 V, this switching regulator is ideal for the power supply of an LCD or for portable systems that operate on a low voltage. The internal oscillation frequency can be set up to 1.133 MHz, via the resistor connected to the ROSC pin. The maximum duty ratio of PWM control can be controlled by the resistor connected to the RDuty pin. The soft-start function at power application is accomplished by combining the reference voltage control and maximum duty control methods. Even if the voltage of the FB pin is retained lower than the reference voltage due to the factor outside the IC, the output voltage is raised by controlling the maximum duty. The phase compensation and gain value can be adjusted according to the values of the resistor and capacitor connected to the CC pin. Therefore, the operation stability and transient response can be correctly set for each application. The reference voltage accuracy is as high as 1.0 V ±1.5%, and any voltage can be output by using an external output voltage setting resistor. In addition, the delay time of the short-circuit protection circuit can be set by using the capacitor connected to the CSP pin. If the maximum duty condition continues because of short-circuiting, the capacitor externally connected to the CSP pin is charged, and oscillation stops after a specific time. The short-circuit protection function is cancelled when the power supply is raised to the UVLO release voltage after it has been lowered to the UVLO detection voltage. A ceramic capacitor or a tantalum capacitor is used as the output capacitor, depending on the setting. This controller IC allows various settings and selections and employs a small package, making it very easy to use. Features • Low voltage operation: • Oscillation frequency: • Maximum duty: • • • • • • • • 1.8 V to 6.0 V 286 kHz to 1.133 MHz (selectable by external resistor) Settable up to 88.5% by external resistor 47 to 88.5% (oscillation frequency; 500 kHz or more) 47 to 80% (oscillation frequency; less than 500 kHz) Reference voltage: 1.0 V ±1.5% Range of operation temperature: −40 to +85°C UVLO (under-voltage lockout) function: Detection voltage can be selected from between 1.5 V and 2.3 V in 0.1 V step. Hysteresis width can be selected from between 0.1 V and 0.3 V in 0.1 V step. Timer latch short-circuit protection circuit: Delay time can be set using an external capacitor. Soft-start function: Soft-start time can be selected in three steps, 10 ms, 15 ms, and 20 ms. Both reference voltage control and maximum duty control methods are applied Phase compensation external setting: Control is possible via the resistor connected between the CC and GND pins and capacitor Small package: SNT-8A, 8-Pin TSSOP Lead-free products Applications • Power supplies for LCDs and CCDs • Power supplies for portable equipment Packages Package Name SNT-8A 8-Pin TSSOP Drawing Code Package Tape Reel Land PH008-A FT008-A PH008-A FT008-E PH008-A FT008-E PH008-A  Seiko Instruments Inc. 1 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Block Diagram VOUT SD L RDuty VIN UVLO M1 CIN ROSC + PWM − comparator Timer latch short-circuit protection circuit EXT VSS CSP + Error amplifier − Reference voltage (1.0 V) soft-start circuit CC RZ CZ Figure 1 Block Diagram 2 CFB RFB1 Oscillator Maximum duty soft-start circuit Seiko Instruments Inc. CL FB RFB2 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Product Name Structure 1. Product name S-8333 A x x x - xxxx G Package name(abbreviation) and packing specifications I8T1: SNT-8A, Tape T8T1: 8-Pin TSSOP, Tape Soft-start time setting A: 10 ms B: 15 ms C: 20 ms UVLO setting A: 2.3 V B: 2.2 V C: 2.1 V D: 2.0 V E: 1.9 V F: 1.8 V G: 1.7 V H: 1.6 V I: 1.5 V UVLO hysteresis setting A: 0.1 V B: 0.2 V C: 0.3 V Seiko Instruments Inc. 3 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Pin Configurations Table 1 SNT-8A Top view Pin No. Symbol Description 1 CC Error amplifier circuit output phase compensation pin Output voltage feedback pin 1 8 2 FB 2 7 3 CSP Short-circuit protection delay time setting pin 3 6 4 VIN Power supply input pin 5 5 EXT External transistor connection pin 6 VSS GND pin 7 ROSC Oscillation frequency setting resistor connection pin 8 RDuty Maximum duty setting resistor connection pin 4 Figure 2 Table 2 8-Pin TSSOP Top view 8 7 6 5 1 2 3 4 Figure 3 4 Pin No. Symbol Description 1 CC Error amplifier circuit output phase compensation pin 2 FB Output voltage feedback pin 3 CSP Short-circuit protection delay time setting pin 4 VIN Power supply input pin 5 EXT External transistor connection pin 6 VSS GND pin 7 ROSC Oscillation frequency setting resistor connection pin 8 RDuty Maximum duty setting resistor connection pin Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Absolute Maximum Ratings Table 3 Absolute Maximum Ratings (Unless otherwise specified: Ta = 25°C, VSS = 0 V) Parameter VIN pin voltage FB pin voltage EXT pin voltage CSP pin voltage CC pin voltage CC pin current ROSC pin voltage ROSC pin current RDuty pin voltage RDuty pin current SNT-8A Power dissipation 8-Pin TSSOP Symbol VIN VFB VEXT VCSP VCC ICC VROSC IROSC VRDuty IRDuty PD Operating ambient temperature Storage temperature Topr Tstg Ratings VSS − 0.3 to VSS + 6.5 VSS − 0.3 to VSS + 6.5 VSS − 0.3 to VIN + 0.3 VSS − 0.3 to VIN + 0.3 VSS − 0.3 to VIN + 0.3 ±10 VSS − 0.3 to VIN + 0.3 ±10 VSS − 0.3 to VIN + 0.3 ±10 450*1 300 (When not mounted on board) 700*1 −40 to +85 −40 to +125 Unit V V V V V mA V mA V mA mW mW mW °C °C *1. When mounted on board [Mounted board] (1) Board size: (2) Name: The absolute maximum ratings are rated values exceeding which the product could suffer physical damage. These values must therefore not be exceeded under any conditions. 800 Power dissipation (PD) [mW] Caution 114.3 mm × 76.2 mm × t1.6 mm JEDEC STANDARD51-7 600 8-Pin TSSOP SNT-8A 400 200 0 0 50 100 150 Ambient temperature (Ta) [°C] Figure 4 Power Dissipation of Package (When mounted on board) Seiko Instruments Inc. 5 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Electrical Characteristics Table 4 Electrical Characteristics (Unless otherwise specified: VIN = 3.3 V, Ta = 25°C) Parameter Symbol Operating input voltage VIN FB voltage VFB Current consumption ISS1 IEXTH IEXTL FB voltage temperature ∆VFB coefficient ∆Ta FB pin input current IFB EXT pin output current Oscillation frequency*1 fosc Oscillation frequency ∆fosc temperature coefficient ∆Ta Max. duty*2 MaxDuty Soft-start time tSS Short-circuit protection tPRO *3 delay time UVLO detection voltage VUVLO UVLO hysteresis width VUVLOHYS CC pin output current ICCH ICCL VRTLT1 Timer latch reset voltage VRTLT2 Conditions Min. Typ. Max. Unit Test Circuit   1.8 0.985  1.000 6.0 1.015 V V 2 2 fosc = 700 kHz VFB = 0.95 V VEXT = VIN − 0.4 V VEXT = 0.4 V  450 700 µA 1  100 −100 160 −60  mA mA 1 1 Ta = −40 to +85°C  ±100  ppm/°C 2 −0.1  +0.1 µA 1 fosc × 0.9 fosc fosc × 1.1 kHz 1  1000  ppm/°C 1 % 1  When fosc = 1133 kHz is set (ROSC = 120 kΩ) When fosc = 700 kHz is set (ROSC = 200 kΩ) When fosc = 286 kHz is set (ROSC = 510 kΩ) VFB = 0.9 V Waveform on EXT pin is measured. Ta = −40 to +85°C fosc = 700 kHz fosc = 1133 kHz (ROSC = 120 kΩ) MaxDuty = 88.5% (RDuty = 62 kΩ) MaxDuty = 73% (RDuty = 180 kΩ) MaxDuty = 47% (RDuty = 390 kΩ) fosc = 700 kHz (ROSC = 200 kΩ) MaxDuty = 88.5% (RDuty = 100 kΩ) tSS = 10 ms, 15 ms, 20 ms Selected in three steps tPRO = 50 ms (CSP = 0.1 µF) VUVLO = 1.5 V to 2.3 V Selected in 0.1 V steps VUVLOHYS = 0.1 V to 0.3 V Selected in 0.1 V steps VFB = 2 V VFB = 0 V Within short-circuit protection delay time After short-circuit protection circuit operated MaxDuty MaxDuty MaxDuty +5 −5 tSS × 0.75 tSS tSS × 1.5 ms 1 37.5 50 75 ms 1 V 1 V 1 µA µA 1 1 VUVLO VUVLO VUVLO × 0.95 × 1.05 VUVLOHYS VUVLOHYS VUVLOHYS × 0.6 × 1.4 −75 −50 −37.5 37.5 50 75 0.7 1.0 1.3 V 1 VUVLO × 0.95 VUVLO VUVLO × 1.05 V 1 *1. The recommended range of the resistance (Rosc) for oscillation frequency is Rosc = 120 kΩ to 510 kΩ (fOSC = 286 kHz to 1.133 MHz). This range of oscillation frequency is the typical value when an ideal resistor is connected externally. In actual use, it is necessary to take account the dispersion of an IC (±10%) into this value. *2. Set max. duty; Between 47 and 88.5 % (RDuty/ROSC = 0.5 to 3.2); the oscillation frequency is 500 kHz or more Between 47 and 80 % (RDuty/ROSC = 1.0 to 3.2); the oscillation frequency is less than 500 kHz This range of max. duty is the typical value when an ideal resistor is connected externally. In actual use, it is necessary to take account the dispersion of an IC (±5%) into this value. *3. The short-circuit protection time can be set by the external capacitor. Although the maximum set value by the external capacitor is unlimited under the ideal condition, set CSP = approx. 0.47 µF as a target maximum value due to discharge time of the capacitor. 6 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series External Parts When Measuring Electrical Characteristics Table 5 External Parts Element Name Inductor Diode Output capacitor Transistor Oscillation frequency setting resistor Maximum duty ratio setting resistor Short-circuit protection delay time setting capacitor Output voltage setting resistor 1 Output voltage setting resistor 2 FB pin capacitor Phase compensation resistor Phase compensation capacitor Symbol L SD CL M1 ROSC RDuty Manufacturer TDK Corporation Rohm Co., Ltd.  Sanyo Electric Co., Ltd.   CSP  RFB1 RFB2 CFB RZ CZ      Seiko Instruments Inc. Part Number LDR655312T 10 µH RB491D Ceramic 10 µF MCH3406 200 kΩ (when fOSC = 700 kHz) 300 kΩ (when MaxDuty = 73%) 0.1 µF (when tPRO = 50 ms) 8.2 kΩ (when VOUT = 9.2 V) 1.0 kΩ (when VOUT = 9.2 V) 180 pF 200 kΩ 0.01 µF 7 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Measurement Circuits 1. RZ A CZ CSP CC RDuty FB ROSC CSP VSS VIN EXT ROSC RDuty CIN Oscilloscope Figure 5 2. RFB1 RDuty FB ROSC CFB RZ CZ CC SD RFB2 CL L M1 CIN CSP VSS VIN EXT CSP V Figure 6 8 Seiko Instruments Inc. ROSC RDuty STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Operation 1. Switching control method 1. 1 PWM control The S-8333 Series is a DC-DC converter using a pulse width modulation method (PWM). The pulse width of the S-8333 Series varies from 0% to the maximum duty set by RDuty depending on the load current, but its switching frequency does not change. Consequently, the ripple voltage generated from switching can be removed easily via a filter. 2. Soft-start function For this IC, the built-in soft-start circuit controls the rush current and overshoot of the output voltage when powering on. Reference voltage adjustment and maximum duty control methods are adopted as the soft-start methods. The following describes the soft-start function at power application. In the circuit where the input voltage is not directly output at shutdown by inserting a switch (SW) between the diode (SD) and VOUT output, the VOUT voltage when the VIN voltage is applied with the SW OFF stays 0 V. Therefore, the voltage of the FB pin stays 0 V and the EXT output is in the step up status between the “H” and “L” levels due to the maximum duty. The maximum duty at this time is approximately 7% and the rush current at power application is controlled. The maximum duty soft start is accomplished by gradually increasing the duty width up to the maximum duty set by the external resistor RDuty (refer to Figure 8). The reference voltage of the error amplifier input also gradually increases from 0 V at the same time as the maximum duty soft start. The increasing of the output voltage is controlled by turning the SW ON. The soft-start function is realized by controlling the voltage of the FB pin so that it is the same potential as the reference voltage that is slowly raised. A Rail-to-Rail amplifier is adopted as the error amplifier, which means that the voltage is loop controlled so that it can be the same as the reference voltage. Once the reference voltage rises, the voltage cannot be reset (the reference voltage is 0 V) unless making the power supply voltage lower than the UVLO detection voltage. Conversely, when the power supply voltage rises up to the reset voltage after it is lowered to the UVLO detection voltage or lower, the output voltage is stepped up by the soft-start function. SD SW VOUT L PWM Comparator VIN M1 − EXT CC RFB1 0.5 V 0V + FB Error amplifier + Error amplifier − reference voltage RZ CL RFB2 Vref CZ Figure 7 Seiko Instruments Inc. 9 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series (VIN = 0 V→3.3 V, VOUT = 9.2 V, RFB1 = 8.2 kΩ, RFB2 = 1.0 kΩ) 3.3 V Input voltage (VIN) 0V tSS Output voltage (VOUT) 9.2 V VOUT×0.95 SW : ON 0V 1.0 V Error amplifier reference voltage 0V Reference voltage soft-start period 1.0 V FB pin voltage (VFB) 0V 3.3 V EXT pin voltage (VEXT) 0V Maximum duty soft-start period t (ms) Figure 8 10 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 3. Timer latch short-circuit protection function This IC has a timer latch short-circuit protection circuit that stops the switching operation when the output voltage drops for a specific time due to output short-circuiting. A capacitor (CSP) that is used to set the delay time of this short-circuit protection circuit can be connected to the CSP pin. This IC operates at the maximum duty ratio if the output voltage drops due to output short-circuiting. At the maximum duty ratio, constant-current charging of CSP starts. If this status lasts for a short-circuit protection delay time and the CSP pin voltage rises above the reference voltage, the latch mode is set. Note that the latch mode is different from the shutdown status in that the switching operation is stopped but the internal circuitry operates normally. To reset the latch operation to protect the IC from short-circuiting, lower VIN than the UVLO detection voltage. The latch mode within the short-circuit protection delay time is reset by decreasing VIN to 1.0 V (Typ.) or lower. Note that the mode is not reset even if the VIN is lowered to the UVLO detection voltage (refer to Figure 9). Input voltage (VIN) UVLO release UVLO detection 1.0 V Output load CSP pin voltage (VCSP) Short-circuit status Reference voltage 50 ms (CSP = 0.1 µF) Latch mode Normal status Short-circuit protection time Latch period Short-circuit protection time Reset period Short-circuit protection time Reset period Figure 9 4. UVLO function This IC includes a UVLO (under-voltage lockout) circuit to prevent the IC from malfunctioning due to a transient status when power is applied or a momentary drop of the power supply voltage. When UVLO is in the detection state, switching is stopped and the external FET is held in the off status. Once UVLO enters the detection state, the soft-start function is reset. Note that the other internal circuits operate normally and that the status is different from the power-off status. Seiko Instruments Inc. 11 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 5. Error amplifier The error amplifier outputs the PWM control signal so that the voltage of the FB pin is held at a specific value (1 V). By connecting a resistor (RZ) and capacitor (CZ) to the output pin (CC pin) of the error amplifier in series, an optional loop gain can be set, enabling stabilized phase compensation. 6. Operation The following are basic equations [(1) through (7)] of the step-up switching regulator (refer to Figure 10). L CONT VIN D VOUT EXT M1 FB CL VSS Figure 10 Step-up Switching Regulator Circuit for Basic Equations Voltage at the CONT pin at the moment M1 is turned ON (current IL flowing through L is zero), VA: *1 VA = VS ................................................................................................................................................. (1) *1. VS: Non-saturated voltage of M1 Change in IL over time: V − VS dl L V ............................................................................................................................. (2) = L = IN dt L L Integration of the above equation:  V − VS  IL =  IN  t .................................................................................................................................... (3) L   IL flows while M1 is ON (ton). This time is determined by the oscillation frequency of OSC. Peak current (IPK) after tON:  V − VS  IPK =  IN  t ON .............................................................................................................................. (4) L   The energy stored in L is represented by 1 2 L (IPK ) . 2 When M1 is turned OFF (tOFF), the energy stored in L is released via a diode, generating a reverse voltage (VL). VL : ( VL = VOUT + VD *2. *2 )− V IN ......................................................................................................................... (5) VD: Diode forward voltage The voltage on the CONT pin rises only by VOUT + VD. 12 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Change in current (IL) flowing through the diode into VOUT during tOFF: + VD − VIN V dI L V ................................................................................................................. (6) = L = OUT dt L L Integration of the above equation is as follows: + VD − VIN  V IL = IPK −  OUT  t ............................................................................................................... (7) L   During tON, energy is stored in L and is not transmitted to VOUT. When receiving output current (IOUT) from VOUT, the energy of the capacitor (CL) is used. As a result, the pin voltage of CL is reduced, and goes to the lowest level after M1 is turned ON (tON). When M1 is turned OFF, the energy stored in L is transmitted via the diode to CL, and the pin voltage of CL rises drastically. Because VOUT is a time function indicating the maximum value (ripple voltage: Vp-p) when the current flowing through the diode into VOUT and the load current IOUT match. Next, this ripple voltage is determined as follows. IOUT vs t1 (time) from after tON, when VOUT reaches the maximum level: + VD − VIN V IOUT = IPK −  OUT L    t 1 .......................................................................................................... (8)    L  ......................................................................................................... (9) ∴ t 1 = (IPK − IOUT )   + − V V V D IN   OUT When tOFF, IL = 0 (when the energy of the inductor is completely transmitted): Based on equation (7),  L  V  OUT + V D − V IN  t  = OFF ............................................................................................................ (10)  I PK  When substituting equation (10) for equation (9):  I t 1 = t OFF −  OUT  IPK   t OFF .................................................................................................................... (11)   Electrical charge ∆Q1 which is charged in CL during t1: ∆Q1 = t1 ∫0 t1 ∫0 IL dt = IPK dt − V OUT + V D − V IN L t1 ∫0 tdt = IPK t 1 − V OUT + V D − V IN 1 2 t 1 ................. (12) L 2 When substituting equation (12) for equation (9): ∆ Q 1 = IPK − = IPK + I OUT t 1 ................................................................................... (13) 2  I PK + I OUT  2    t 1 ................................................................................................... (14)  1 (IPK − I OUT 2 ) t1 A rise voltage (Vp-p) due to ∆Q1: VP −P = ∆Q 1 1 = CL CL When taking into consideration IOUT consumed during t1 and ESR*1 (RESR) of CL: VP −P = *1. ∆Q1 1 = CL CL  IPK + I OUT  2  + I OUT  I   t 1 +  PK 2   I t   R ESR − OUT 1 .............................................. (15) CL  Equivalent Series Resistance When substituting equation (11) for equation (15): VP −P = (I PK − I OUT ) 2 t OFF + I OUT  I +  PK 2 IPK CL 2    R ESR ........................................................................... (16)  Therefore to reduce the ripple voltage, it is important that the capacitor connected to the output pin has a large capacity and a small ESR. Seiko Instruments Inc. 13 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series External Parts Selection 1. Inductor The inductance has a strong influence on the maximum output current (IOUT) and efficiency (η). The peak current (IPK) increases by decreasing L and the stability of the circuit improves and IOUT increases. If L is decreased further, the efficiency falls, and IOUT decreases if the current drive capability of the external transistor is insufficient. The loss of IPK by the switching transistor decreases by increasing L and the efficiency becomes maximum at a certain L value. Further increasing L decrease the efficiency due to the loss of the DC resistance of the inductor. IOUT also decreases. If the oscillation frequency is higher, a smaller L value can be chosen, making the inductor smaller. In the S-8333 Series, the oscillation frequency can be varied within the range of 286 kHz to 1.133 MHz by the external resistor, so select an L value best suited to the frequency. The recommended value is between 2.2 µH and 22 µH. When selecting an inductor, note the allowable current of the inductor. If a current exceeding this allowable current flows through the inductor, magnetic saturation occurs, substantially lowering the efficiency and increasing the current, which results in damage to the IC. Therefore, select an inductor so that IPK does not exceed the allowable current. IPK is expressed by the following equations in the discontinuous mode and continuous mode. I PK = I PK = 2 I OUT (V OUT fosc + V D − V IN ) L ( discontinuous mode ) .................................................................. (17) (V OUT + V D − V IN ) V IN V OUT + V D I OUT + V IN 2 (V OUT + V D ) fosc L (continuous mode) ........................................................ (18) fOSC = Oscillation frequency, VD ≅ 0.4 V. 2. Diode Use an external diode that meets the following requirements. • Low forward voltage • High switching speed • Reverse breakdown voltage: VOUT + [Spike voltage] or more • Rated current: IPK or more 3. Capacitors (CIN, CL) The capacitor on the input side (CIN) can lower the supply impedance and level the input current for better efficiency. Select CIN according to the impedance of the power supply to be used. The capacitor on the output side (CL) is used to smooth the output voltage. Select an appropriate capacitance value based on the I/O conditions and load conditions. A capacitance of 10 µF or more is recommended. By adjusting the phase compensation of the feedback loop using the external resistor (RZ) and capacitor (CZ), a ceramic capacitor can be used as the capacitor on the output side. If a capacitor whose equivalent series resistance is between 30 mΩ and 500 mΩ is used as the output capacitor, the adjustable range of the phase compensation is wider; however, note that other characteristics may be affected by ripple voltage or other conditions at this time. The optimal capacitor differs depending on the L value, capacitance value, wiring, and application (output load), so select the capacitor after performing sufficient evaluation under the actual usage conditions. 14 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 4. External transistor A bipolar (NPN) or enhancement (N-channel) MOS FET transistor can be used as the external capacitor. 4. 1 Bipolar (NPN) type The driving capability when the output current is increased by using a bipolar transistor is determined by hFE and Rb of the bipolar transistor. Figure 11 shows a peripheral circuit. VIN Cb 2200 pF Pch IPK Rb EXT 1 kΩ Nch Figure 11 External Transistor Periphery 1 kΩ is recommended for Rb. Actually, calculate the necessary base current (Ib) from hFE of the bipolar transistor as follows and select an Rb value lower than this. Ib = Rb = IPK hFE VIN − 0.7 Ib − 0.4 IEXTH A small Rb increases the output current, but the efficiency decreases. Actually, a pulsating current flows and a voltage drop occurs due to the wiring capacitance. Determine the optimum value by experiment. A speed-up capacitor (Cb) connected in parallel with Rb resistance as shown in Figure 11 decreases the switching loss and improves the efficiency. Select Cb by observing the following equation. 1 Cb ≤ 2 π R b f OSC 0.7 However, in practice, the optimum Cb value also varies depending on the characteristics of the bipolar transistor employed. Therefore, determine the optimum value of Cb by experiment. 4. 2 Enhancement MOS FET type Use an Nch power MOS FET. For high efficiency, using a MOS FET with a low ON resistance (RON) and small input capacitance (CISS) is ideal, however, ON resistance and input capacitance generally share a trade-off relationship. The ON resistance is efficient in a range in which the output current is relatively great during low-frequency switching, and the input capacitance is efficient in a range in which the output current is middling during high-frequency switching. Select a MOS FET whose ON resistance and input capacitance are optimal depending on the usage conditions. The input voltage (VIN) is supplied for the gate voltage of the MOS FET, so select a MOS FET with a gate withstanding voltage that is equal to the maximum usage value of the input voltage or higher and a drain withstanding voltage that is equal to the amount of the output voltage (VOUT) and diode voltage (VD) or higher. If a MOS FET with a threshold that is near the UVLO detection voltage is used, a large current may flow, stopping the output voltage from rising and possibly generating heat in the worst case. Select a MOS FET with a threshold that is sufficiently lower than the UVLO detection voltage value. Seiko Instruments Inc. 15 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 5. Oscillation frequency and maximum duty ratio setting resistors (ROSC, RDuty) With the S-8333 Series, the oscillation frequency can be set in a range of 286 kHz to 1.133 MHz using external resistance. Connect a resistor across the ROSC and VSS pins. Select the resistor by using the following equation and referring to Figure 12. However, the following equation and figure assume that the resistance value is the desired value and show the theoretical values when the IC is in the typical conditions. Note that fluctuations of resistance and IC are not considered. 140 × 103 fOSC [kHz] 1400 1200 fOSC [kHz] ROSC [kΩ] ≅ 1000 800 600 400 200 0 0 600 400 200 ROSC [kΩ] Figure 12 ROSC vs. fOSC With the S-8333 Series, the maximum duty ratio can be set in a range of 47% to 88.5% (between 47 to 80%, if the oscillation frequency is less than 500 kHz) by an external resistor. Connect the resistor across the RDuty and VSS pins. Select the resistance by using the following equation and referring to Figure 13. The maximum duty ratio fluctuates according to the oscillation frequency. If the value of ROSC is changed, therefore, be sure to change the value of RDuty so that it is always in proportion to RDuty / ROSC. However, the following equation and figure assume that the resistance value is the desired value and show the theoretical values when the IC is in the typical conditions. Note that fluctuations of resistance and IC are not considered. Caution Set max. duty 80% or less if the oscillation frequency is less than 500 kHz. RDuty (95.5 − MaxDuty) 100 15.0 90 MaxDuty [%] ROSC ≅ 80 70 60 50 40 0 1 2 3 RDuty / ROSC Figure 13 RDuty / ROSC vs. MaxDuty Connect resistors ROSC and RDuty as close to the IC as possible. 16 Seiko Instruments Inc. 4 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 6. Short-circuit protection delay time setting capacitor (CSP) With the S-8333 Series, the short-circuit protection delay time can be set to any value by an external capacitor. Connect the capacitor across the CSP and VSS pins. Select the capacitance by using the following equation and referring to Figure 14. However, the following equation and figure assume that the capacitor value is the desired value and show the theoretical values when the IC is in the typical conditions. Note that fluctuations of capacitor and IC are not considered. tPRO [ms] × 2 × 10−3 120 1.0 100 tPRO [ms] CSP [µF] ≅ 80 60 40 20 0 0 0.05 0.10 0.15 0.20 0.25 CSP [µF] Figure 14 CSP vs. tPRO 7. Output voltage setting resistors (RFB1, RBF2) With the S-8333 Series, the output voltage can be set to any value by external divider resistors. Connect the divider resistors across the VOUT and VSS pins. Because VFB = 1 V, the output voltage can be calculated by this equation. VOUT = (RFB1 + RFB2) RFB2 Connect divider resistors RFB1 and RFB2 as close to the IC to minimize effects from of noise. If noise does have an effect, adjust the values of RFB1 and RFB2 so that RFB1 + RFB2 < 100 kΩ. CFB connected in parallel with RFB1 is a capacitor for phase compensation. Select the optimum value of this capacitor at which the stable operation can be ensured from the values of the inductor and output capacitor. 8. Phase compensation setting resistor and capacitor (RZ, CZ) The S-8333 Series needs appropriate compensation for the voltage feedback loop to prevent excessive output ripple and unstable operation from deteriorating the efficiency. This compensation is implemented by connecting RZ and CZ in series across the CC and VSS pins. RZ sets the high-frequency gain for a high-speed transient response. CZ sets the pole and zero of the error amplifier and keeps the loop stable. Adjust RZ and CZ, taking into consideration conditions such as the inductor, output capacitor, and load current, so that the optimum transient characteristics can be obtained. Seiko Instruments Inc. 17 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Standard Circuit SD L VOUT RDuty VIN UVLO M1 CIN ROSC + PWM − comparator EXT + Timer latch short-circuit protection circuit 0.1 µF VSS CSP CFB RFB1 Oscillator Maximum duty soft-start circuit Error amplifier − Reference voltage (1.0 V) soft-start circuit CL ROSC RDuty FB RFB2 CC RZ CZ Ground point Figure 15 Standard Circuit Caution 18 The above connection diagram and constant will not guarantee successful operation. Perform thorough evaluation using the actual application to set the constant. Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Precaution • Mount external capacitors, diodes, and inductor as close as possible to the IC. • Characteristics ripple voltage and spike noise occur in IC containing switching regulators. Moreover rush current flows at the time of a power supply injection. Because these largely depend on the inductor, the capacitor and impedance of power supply used, fully check them using an actually mounted model. • Make sure the dissipation of the switching transistor (especially at a high temperature) does not exceed the allowable power dissipation of the package. • The performance of a switching regulator varies depending on the design of the PCB patterns, peripheral circuits, and external parts. Thoroughly test all settings with your device. • The capacitor, diode, inductor and others used as external parts do not assure the operation at high temperature. Evaluate fully using the actual application when designing. • This IC builds in soft start function, starts reference voltage gradually, and it is controlled so that FB pin voltage and reference voltage become this potential. Therefore, keep in mind that it will be in a maximum duty state according to the factor of IC exterior if FB pin voltage is held less than reference voltage. • Although the IC contains a static electricity protection circuit, static electricity or voltage that exceeds the limit of the protection circuit should not be applied. • Seiko Instruments Inc. assumes no responsibility for the way in which this IC is used on products created using this IC or for the specifications of that product, nor does Seiko Instruments Inc. assume any responsibility for any infringement of patents or copyrights by products that include this IC either in Japan or in other countries. Seiko Instruments Inc. 19 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Characteristics (Typical Data) 1. Example of Major Temperature Characteristics (Ta = −40 to 85°C) ISS1 [µA] ISS1 vs. Ta (VIN = 3.3 V) 800 fOSC = 1133 kHz (ROSC = 120 kΩ) 700 600 fOSC = 700 kHz (ROSC = 200 kΩ) 500 400 300 fOSC = 286 kHz (ROSC = 510 kΩ) 200 100 0 −40 −20 0 20 40 60 80 100 Ta [°C] 100 MaxDuty [%] 100 fOSC vs. Ta (VIN = 3.3 V) 1400 fOSC = 1133 kHz (ROSC = 120 kΩ) 1200 1000 fOSC = 700 kHz (ROSC = 200 kΩ) 800 600 fOSC = 286 kHz (ROSC = 510 kΩ) 400 200 0 −40 −20 0 20 40 60 80 100 Ta [°C] 60 80 100 tSS vs. Ta (VIN = 3.3 V) 25.0 tSS = 20 ms 20.0 tSS [ms] 20 40 Ta [°C] MaxDuty vs. Ta (VIN = 3.3 V) 100 90 MaxDuty = 88.5% (ROSC = 200 kΩ, RDuty = 100 kΩ) 80 70 MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) 60 50 40 MaxDuty = 47% (ROSC = 200 kΩ, RDuty = 640 kΩ) 30 20 10 0 −40 −20 0 20 40 60 80 100 Ta [°C] 20 80 fOSC [kHz] 80 IFB [µA] IFB vs. Ta (VIN = 3.3 V) 0.10 0.08 0.06 0.04 0.02 0 −0.02 −0.04 −0.06 −0.08 −0.10 −40 −20 0 IEXTL vs. Ta (VIN = 3.3 V) 200 180 160 140 120 100 80 60 fOSC = 700 kHz, MaxDuty = 73% 40 (ROSC = 200 kΩ, RDuty = 300 kΩ) 20 0 −40 −20 0 20 40 60 Ta [°C] IEXTL [mA] IEXTH [mA] IEXTH vs. Ta (VIN = 3.3 V) −200 −180 −160 −140 −120 −100 −80 −60 fOSC = 700 kHz, MaxDuty = 73% −40 (ROSC = 200 kΩ, RDuty = 300 kΩ) −20 0 −40 −20 0 20 40 60 Ta [°C] 15.0 tSS = 10 ms 10.0 5.0 0 −40 −20 Seiko Instruments Inc. 0 20 40 Ta [°C] 60 80 100 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series VUVLO vs. Ta 2.5 VUVLOHYS vs. Ta 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0 −40 −20 ICCH vs. Ta (VIN = 3.3 V) −100 −90 −80 −70 −60 −50 −40 −30 −20 −10 0 −40 −20 0 20 40 Ta [°C] VUVLO = 2.3 V 1.5 VUVLO = 1.5 V 1.0 0.5 0 −40 −20 0 20 40 Ta [°C] 60 80 100 60 80 100 60 80 100 ICCH [µA] VUVLOHYS [V] VUVLOHYS = 0.3 V 2.0 VUVLO [V] tPRO [ms] tPRO vs. Ta (VIN = 3.3 V) 70.0 tPRO = 50 ms (CSP = 0.1 µF) 60.0 50.0 40.0 30.0 20.0 10.0 0 −40 −20 0 20 40 60 80 100 Ta [°C] VUVLOHYS = 0.1 V 20 40 Ta [°C] 80 100 VRTLT1 vs. Ta (VIN = 3.3 V) 1.2 1.0 ICCL [µA] ICCL vs. Ta (VIN = 3.3 V) 100 90 80 70 60 50 40 30 20 10 0 −40 −20 0 20 40 Ta [°C] 60 VRTLT1 [V] 0 0.8 0.6 0.4 0.2 60 80 100 0 −40 −20 Seiko Instruments Inc. 0 20 40 Ta [°C] 21 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 2. Example of Major Power Supply Dependence Characteristics (Ta = 25°C) ISS1 [µA] ISS vs. VIN 1400 fOSC = 1133 kHz 1200 (ROSC = 120 kΩ) 1000 fOSC = 700 kHz 800 (ROSC = 200 kΩ) 600 400 fOSC = 286 kHz 200 (ROSC = 510 kΩ) 0 7 1 0 2 3 4 5 6 VIN [V] 6 7 MaxDuty [%] fOSC [kHz] 2 3 4 VIN [V] 5 6 7 7 600 400 200 0 6 7 fOSC = 286 kHz (ROSC = 510 kΩ) 0 1 2 3 4 VIN [V] 5 tSS vs. VIN 25.0 20.0 MaxDuty = 88.5% (ROSC = 200 kΩ, RDuty = 100 kΩ) tSS [ms] 1 MaxDuty vs. VIN 100 90 80 70 60 50 40 30 20 10 0 1 0 22 6 fOSC vs. VIN 1400 1200 fOSC = 1133 kHz (ROSC = 120 kΩ) 1000 800 fOSC = 700 kHz (ROSC = 200 kΩ) IFB [µA] IFB vs. VIN 0.10 0.08 0.06 0.04 0.02 0 −0.02 −0.04 −0.06 −0.08 −0.10 0 IEXTL vs. VIN 200 180 160 140 120 100 80 60 fOSC = 700 kHz, MaxDuty = 73% 40 (ROSC = 200 kΩ, RDuty = 300 kΩ) 20 0 1 0 2 3 4 5 VIN [V] IEXTL [mA] IEXTH [mA] IEXTH vs. VIN −200 −180 −160 −140 −120 −100 −80 −60 fOSC = 700 kHz, MaxDuty = 73% −40 (ROSC = 200 kΩ, RDuty = 300 kΩ) −20 0 1 0 2 3 4 5 VIN [V] MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) MaxDuty = 47% (ROSC = 200 kΩ, RDuty = 640 kΩ) tSS = 20 ms 15.0 10.0 tSS = 10 ms 5.0 0 2 3 4 VIN [V] 5 6 7 0 Seiko Instruments Inc. 1 2 3 4 VIN [V] 5 6 7 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series tPRO vs. VIN 70.0 60.0 50.0 40.0 30.0 20.0 10.0 0 0 1 2 3 4 VIN [V] 5 6 7 ICCL vs. VIN 100 90 80 70 60 50 40 30 20 10 0 0 1 2 3 4 VIN [V] 5 6 7 ICCH [µA] tPRO [ms] tPRO=50 ms (CSP = 0.1 µF) ICCH vs. VIN −100 −90 −80 −70 −60 −50 −40 −30 −20 −10 0 0 2 3 4 VIN [V] 5 6 7 ICCL [µA] 1 Seiko Instruments Inc. 23 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 3. Example of External Parts Dependence Characteristics fOSC [kHz] fOSC vs. ROSC (VIN = 3.3 V) 1600 1400 Ta = −40°C 1200 Ta = 25°C 1000 Ta = 85°C 800 600 400 200 0 100 200 300 400 500 0 ROSC [kΩ] 600 MaxDuty [%] MaxDuty vs. RDuty / ROSC (ROSC = 200 kΩ, VIN = 3.3 V) 100 90 Ta = −40°C 80 Ta = 25°C 70 Ta = 85°C 60 50 40 30 20 10 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 RDuty / ROSC tPRO [ms] tPRO vs. CSP (VIN = 3.3 V) 350 300 250 200 150 100 50 0 0.1 0 0.2 0.3 CSP [µF] 24 Ta = −40°C Ta = 25°C Ta = 85°C 0.4 0.5 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 4. Examples of Transient Response Characteristics 4.1 Powering ON (VOUT = 9.2 V, VIN = 0 V → 3.3 V, Ta = 25°C) Remark The switch (SW) is inserted between the diode (SD) and VOUT output. Controlled externally to turn SW on a few ms later after the VIN voltage is applied. (2) fOSC = 1133 kHz, IOUT = 100 mA, tSS = 10 ms 8 4 0 2 0 5 10 time [ms] 15 4 2 0 −5 20 (3) fOSC = 700 kHz, IOUT = 0 mA, tSS = 10 ms 0 0 5 10 time [ms] 15 20 (4) fOSC = 700 kHz, IOUT = 100 mA, tSS = 10 ms 12 8 4 0 2 0 −5 0 5 10 time [ms] 15 8 4 VIN [V] VIN [V] 4 VOUT [V] 12 4 (5) fOSC = 286 kHz, IOUT = 0 mA, tSS = 10 ms 0 2 0 −5 20 0 5 10 time [ms] 15 20 (6) fOSC = 286 kHz, IOUT = 100 mA, tSS = 10 ms 12 4 0 2 0 −5 0 5 10 time [ms] 15 20 8 4 VIN [V] VIN [V] 4 VOUT [V] 12 8 VOUT [V] 0 4 4 VOUT [V] −5 12 8 VIN [V] VIN [V] 4 VOUT [V] 12 VOUT [V] (1) fOSC = 1133 kHz, IOUT = 0 mA, tSS = 10 ms 0 2 0 −5 Seiko Instruments Inc. 0 5 10 time [ms] 15 20 25 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 4.2 Load fluctuations (VOUT = 9.2 V, VIN = 3.3 V, Ta = 25°C, RZ = 200 kΩ, CZ = 0.01 µF) (1) fOSC = 1133 kHz, IOUT = 0.1 mA→100 mA IOUT 100 mA (2) fOSC = 1133 kHz, IOUT = 100 mA→0.1 mA 10.0 0.1 mA 9.8 IOUT 100 mA 9.6 0.1 mA 10.0 9.8 9.6 9.4 9.2 VOUT [0.2 V/div] −20 9.0 −10 0 time [ms] 10 20 (3) fOSC = 700 kHz, IOUT = 0.1 mA→100 mA IOUT 100 mA 8.8 9.4 9.2 VOUT [0.2 V/div] −20 9.0 −10 0 time [ms] 10 20 (4) fOSC = 700 kHz, IOUT = 100 mA→0.1 mA 10.0 0.1 mA 9.8 IOUT 100 mA 9.6 0.1 mA 10.0 9.8 9.6 9.4 9.2 VOUT [0.2 V/div] −20 9.0 −10 0 time [ms] 10 20 (5) fOSC = 286 kHz, IOUT = 0.1 mA→100 mA IOUT 100 mA 8.8 9.4 9.2 VOUT [0.2 V/div] −20 9.0 −10 0 time [ms] 10 20 9.8 IOUT 100 mA 9.6 0.1 mA 10.0 9.8 9.6 9.4 9.2 VOUT [0.2 V/div] 26 9.0 −10 0 time [ms] 10 8.8 (6) fOSC = 286 kHz, IOUT = 100 mA→0.1 mA 10.0 0.1 mA −20 8.8 20 8.8 9.4 9.2 VOUT [0.2 V/div] −20 Seiko Instruments Inc. 9.0 −10 0 time [ms] 10 20 8.8 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 4.3 Input voltage fluctuations (VOUT = 9.2 V, IOUT = 100 mA, RZ = 200 kΩ, CZ = 0.01 µF) (1) fOSC = 1133 kHz, VIN = 2.8 V→3.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 −10 0 time [ms] 10 (3) fOSC = 700 kHz, VIN = 2.8 V→3.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 −10 0 time [ms] 10 (5) fOSC = 286 kHz, VIN = 2.8 V→3.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 −10 0 time [ms] 10 9.40 9.30 VOUT 9.20 [V] 9.10 20 9.40 9.30 VOUT 9.20 [V] 9.10 20 9.40 9.30 VOUT 9.20 [V] 9.10 20 (2) fOSC = 1133 kHz, VIN = 3.8 V→2.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 −10 0 time [ms] 10 (4) fOSC = 700 kHz, VIN = 3.8 V→2.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 −10 0 time [ms] 10 (6) fOSC = 286 kHz, VIN = 3.8 V→2.8 V 4.0 VIN 3.5 [V] 3.0 2.5 −20 Seiko Instruments Inc. −10 0 time [ms] 10 9.40 9.30 VOUT 9.20 [V] 9.10 20 9.40 9.30 VOUT 9.20 [V] 9.10 20 9.40 9.30 VOUT 9.20 [V] 9.10 20 27 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Reference Data 1. Reference data for external parts Table 6 Properties of External Parts Element Name Inductor Diode Output capacitor (ceramic) Transistor Product Name Manufacture LDR655312T TDK Corporation RB491D Rohm Co., Ltd.   MCH3406 Sanyo Electric Co., Ltd. Characteristics 10 µH, DCR*1 = 307 mΩ, IMAX*2 = 0.7 A, Height = 1.2 mm VF*3 = 0.45 V, IF*4 = 1.0 A 16 V, 10 µF VDSS*5 = 20 V, VGSS*6 = ±10 V, Ciss*7 = 280 pF, RDS(ON)*8 = 82 mΩ max. (VGS*9 = 2.5 V, ID*10 = 1 A) *1. DCR : DC resistance *2. IMAX : Maximum allowable current *3. VF : Forward voltage *4. IF : Forward current *5. VDSS : Drain to source voltage (when short circuited between the gate and source) *6. VGSS : Gate to source voltage (when short circuited between the drain and source) *7. Ciss : Input capacitance *8. RDS(ON) : Drain to source on resistance *9. VGS : Gate to source voltage *10. ID : Drain current Caution The values shown in the characteristics column of Table 6 above are based on the materials provided by each manufacturer. However, consider the characteristics of the original materials when using the above products. 28 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 2. Reference data (1) The data of (a) output current (IOUT) vs. efficiency (η) characteristics and (b) output current (IOUT) vs. output voltage (VOUT) characteristics is shown below. 2. 1 VOUT = 13.1 V (RFB1 = 7.5 kΩ, RFB2 = 620 Ω) (1) fOSC = 1133 kHz, MaxDuty = 73% (ROSC = 120 kΩ, RDuty = 180 kΩ) (b) IOUT vs. VOUT 13.20 VOUT [V] 13.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 1 10 IOUT [mA] 100 13.05 13.00 12.95 VIN = 5.0 V 0.1 13.10 12.90 0.01 1000 VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 1000 (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) (b) IOUT vs. VOUT 13.20 VOUT [V] 13.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 1 10 IOUT [mA] 100 13.05 13.00 12.95 VIN = 5.0 V 0.1 13.10 12.90 0.01 1000 VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 1000 (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) (b) IOUT vs. VOUT 13.20 VOUT [V] 13.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 1000 13.10 13.05 13.00 12.95 12.90 0.01 Seiko Instruments Inc. VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 1000 29 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 2. 2 VOUT = 9.2 V (RFB1 = 8.2 kΩ, RFB2 = 1.0 kΩ) (1) fOSC = 1133 kHz, MaxDuty = 73% (ROSC = 120 kΩ, RDuty = 180 kΩ) (b) IOUT vs. VOUT 9.30 VOUT [V] 9.25 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 3.3 V VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 9.20 9.15 9.10 VIN = 3.3 V VIN = 5.0 V 9.05 9.00 0.01 1000 0.1 1 10 IOUT [mA] 100 1000 (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) (b) IOUT vs. VOUT 9.30 VOUT [V] 9.25 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 3.3 V VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 9.20 9.15 9.10 VIN = 3.3 V VIN = 5.0 V 9.05 9.00 0.01 1000 0.1 1 10 IOUT [mA] 100 1000 (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) (b) IOUT vs. VOUT 9.30 VOUT [V] 9.25 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 30 VIN = 3.3 V VIN = 5.0 V 0.1 1 10 IOUT [mA] 100 1000 9.20 9.15 9.10 VIN = 3.3 V VIN = 5.0 V 9.05 9.00 0.01 Seiko Instruments Inc. 0.1 1 10 IOUT [mA] 100 1000 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 2. 3 VOUT = 6.1 V (RFB1 = 5.1 kΩ, RFB2 = 1.0 kΩ) (1) fOSC = 1133 kHz, MaxDuty = 73% (ROSC = 120 kΩ, RDuty = 180 kΩ) (b) IOUT vs. VOUT 6.20 VOUT [V] 6.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 2.5 V VIN = 3.3 V 0.1 1 10 IOUT [mA] 100 6.10 6.05 6.00 VIN = 2.5 V VIN = 3.3 V 5.95 5.90 0.01 1000 0.1 1 10 IOUT [mA] 100 1000 (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) (b) IOUT vs. VOUT 6.20 VOUT [V] 6.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 2.5 V VIN = 3.3 V 0.1 1 10 IOUT [mA] 100 6.10 6.05 6.00 VIN = 2.5 V VIN = 3.3 V 5.95 5.90 0.01 1000 0.1 1 10 IOUT [mA] 100 1000 (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) (b) IOUT vs. VOUT 6.20 VOUT [V] 6.15 η [%] (a) IOUT vs. η 100 90 80 70 60 50 40 30 20 10 0 0.01 VIN = 2.5 V VIN = 3.3 V 0.1 1 10 IOUT [mA] 100 1000 6.10 6.05 6.00 VIN = 2.5 V VIN = 3.3 V 5.95 5.90 0.01 Seiko Instruments Inc. 0.1 1 10 IOUT [mA] 100 1000 31 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 3. Reference data (2) The data of output current (IOUT) vs. ripple voltage (Vr) characteristics is shown below. 3. 1 VOUT = 13.1 V (RFB1 = 7.5 kΩ, RFB2 = 620 Ω) 100 1000 100 1000 100 1000 100 1000 Vr [mV] (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) 100 90 VIN = 5.0 V 80 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) 100 90 VIN = 5.0 V 80 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] Vr [mV] Vr [mV] (1) fOSC = 1133 kHz, MaxDuty = 73 % (ROSC = 120 kΩ, RDuty = 180 kΩ) 100 90 VIN = 5.0 V 80 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] 3. 2 VOUT = 9.2 V (RFB1 = 8.2 kΩ, RFB2 = 1.0 kΩ) 100 1000 100 1000 Vr [mV] (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) 100 VIN = 3.3 V 90 80 VIN = 5.0 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) 100 90 VIN = 3.3 V 80 VIN = 5.0 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] Vr [mV] Vr [mV] (1) fOSC = 1133 kHz, MaxDuty = 73% (ROSC = 120 kΩ, RDuty = 180 kΩ) 100 90 VIN = 3.3 V 80 VIN = 5.0 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] 32 Seiko Instruments Inc. STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series 3. 3 VOUT = 6.1 V (RFB1 = 5.1 kΩ, RFB2 = 1.0 kΩ) 100 1000 100 1000 100 1000 Vr [mV] (3) fOSC = 286 kHz, MaxDuty = 73% (ROSC = 510 kΩ, RDuty = 750 kΩ) 100 VIN = 2.5 V 90 80 VIN = 3.3 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] (2) fOSC = 700 kHz, MaxDuty = 73% (ROSC = 200 kΩ, RDuty = 300 kΩ) 100 VIN = 2.5 V 90 80 VIN = 3.3 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] Vr [mV] Vr [mV] (1) fOSC = 1133 kHz, MaxDuty = 73% (ROSC = 120 kΩ, RDuty = 180 kΩ) 100 90 VIN = 2.5 V 80 VIN = 3.3 V 70 60 50 40 30 20 10 0 0.1 0.01 1 10 IOUT [mA] Seiko Instruments Inc. 33 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series Marking Specification (1) SNT-8A SNT-8A Top view (1) (2) (3) (4) (9) (10) (11) 4 (5) (6) (7) (8) 1 (1) (2) to (4) (5), (6) (7) to (11) 8 Blank Product code (Refer to Product name vs. Product code) Blank Lot number 5 Product name vs. Product code Product name S-8333AAAA-I8T1G S-8333AAAB-I8T1G S-8333AAAC-I8T1G S-8333AABA-I8T1G S-8333AABB-I8T1G S-8333AABC-I8T1G S-8333AACA-I8T1G S-8333AACB-I8T1G S-8333AACC-I8T1G S-8333AADA-I8T1G S-8333AADB-I8T1G S-8333AADC-I8T1G S-8333AAEA-I8T1G S-8333AAEB-I8T1G S-8333AAEC-I8T1G S-8333AAFA-I8T1G S-8333AAFB-I8T1G S-8333AAFC-I8T1G S-8333AAGA-I8T1G S-8333AAGB-I8T1G S-8333AAGC-I8T1G S-8333AAHA-I8T1G S-8333AAHB-I8T1G S-8333AAHC-I8T1G S-8333AAIA-I8T1G S-8333AAIB-I8T1G S-8333AAIC-I8T1G S-8333ABAA-I8T1G S-8333ABAB-I8T1G S-8333ABAC-I8T1G S-8333ABBA-I8T1G S-8333ABBB-I8T1G S-8333ABBC-I8T1G S-8333ABCA-I8T1G S-8333ABCB-I8T1G S-8333ABCC-I8T1G S-8333ABDA-I8T1G S-8333ABDB-I8T1G S-8333ABDC-I8T1G S-8333ABEA-I8T1G S-8333ABEB-I8T1G 34 (2) O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O Product code (3) (4) F A F B F C F D F E F F F G F H F I F J F K F L F M F N F O F P F Q F R F S F T F U F V F W F X F Y F Z F 3 G A G B G C G D G E G F G G G H G I G J G K G L G M G N Product name S-8333ABEC-I8T1G S-8333ABFA-I8T1G S-8333ABFB-I8T1G S-8333ABFC-I8T1G S-8333ABGA-I8T1G S-8333ABGB-I8T1G S-8333ABGC-I8T1G S-8333ABHA-I8T1G S-8333ABHB-I8T1G S-8333ABHC-I8T1G S-8333ABIA-I8T1G S-8333ABIB-I8T1G S-8333ABIC-I8T1G S-8333ACAA-I8T1G S-8333ACAB-I8T1G S-8333ACAC-I8T1G S-8333ACBA-I8T1G S-8333ACBB-I8T1G S-8333ACBC-I8T1G S-8333ACCA-I8T1G S-8333ACCB-I8T1G S-8333ACCC-I8T1G S-8333ACDA-I8T1G S-8333ACDB-I8T1G S-8333ACDC-I8T1G S-8333ACEA-I8T1G S-8333ACEB-I8T1G S-8333ACEC-I8T1G S-8333ACFA-I8T1G S-8333ACFB-I8T1G S-8333ACFC-I8T1G S-8333ACGA-I8T1G S-8333ACGB-I8T1G S-8333ACGC-I8T1G S-8333ACHA-I8T1G S-8333ACHB-I8T1G S-8333ACHC-I8T1G S-8333ACIA-I8T1G S-8333ACIB-I8T1G S-8333ACIC-I8T1G Seiko Instruments Inc. Product code (2) (3) (4) O G O O G P O G Q O G R O G S O G T O G U O G V O G W O G X O G Y O G Z O G 3 O H A O H B O H C O H D O H E O H F O H G O H H O H I O H J O H K O H L O H M O H N O H O O H P O H Q O H R O H S O H T O H U O H V O H W O H X O H Y O H Z O H 3 STEP-UP, FOR LCD BIAS SUPPLY, 1-CHANNEL, PWM CONTROL SWITCHING REGULATOR CONTROLLER Rev.2.3_00 S-8333 Series (2) 8-Pin TSSOP 8-Pin TSSOP Top view 1 (1) to (4) (5) to (8) 8 (9) to (14) (1) (2) (3) (4) Product name: 8333 (Fixed) Function code (Refer to Product name vs. Function code) Lot number (5) (6) (7) (8) 4 (9) (10) (11) (12) (13) (14) 5 Product name vs. Function code Product name S-8333AAAA-T8T1G S-8333AAAB-T8T1G S-8333AAAC-T8T1G S-8333AABA-T8T1G S-8333AABB-T8T1G S-8333AABC-T8T1G S-8333AACA-T8T1G S-8333AACB-T8T1G S-8333AACC-T8T1G S-8333AADA-T8T1G S-8333AADB-T8T1G S-8333AADC-T8T1G S-8333AAEA-T8T1G S-8333AAEB-T8T1G S-8333AAEC-T8T1G S-8333AAFA-T8T1G S-8333AAFB-T8T1G S-8333AAFC-T8T1G S-8333AAGA-T8T1G S-8333AAGB-T8T1G S-8333AAGC-T8T1G S-8333AAHA-T8T1G S-8333AAHB-T8T1G S-8333AAHC-T8T1G S-8333AAIA-T8T1G S-8333AAIB-T8T1G S-8333AAIC-T8T1G S-8333ABAA-T8T1G S-8333ABAB-T8T1G S-8333ABAC-T8T1G S-8333ABBA-T8T1G S-8333ABBB-T8T1G S-8333ABBC-T8T1G S-8333ABCA-T8T1G S-8333ABCB-T8T1G S-8333ABCC-T8T1G S-8333ABDA-T8T1G S-8333ABDB-T8T1G S-8333ABDC-T8T1G S-8333ABEA-T8T1G S-8333ABEB-T8T1G (5) A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A Function code (6) (7) (8) A A A A A B A A C A B A A B B A B C A C A A C B A C C A D A A D B A D C A E A A E B A E C A F A A F B A F C A G A A G B A G C A H A A H B A H C A I A A I B A I C B A A B A B B A C B B A B B B B B C B C A B C B B C C B D A B D B B D C B E A B E B Product name S-8333ABEC-T8T1G S-8333ABFA-T8T1G S-8333ABFB-T8T1G S-8333ABFC-T8T1G S-8333ABGA-T8T1G S-8333ABGB-T8T1G S-8333ABGC-T8T1G S-8333ABHA-T8T1G S-8333ABHB-T8T1G S-8333ABHC-T8T1G S-8333ABIA-T8T1G S-8333ABIB-T8T1G S-8333ABIC-T8T1G S-8333ACAA-T8T1G S-8333ACAB-T8T1G S-8333ACAC-T8T1G S-8333ACBA-T8T1G S-8333ACBB-T8T1G S-8333ACBC-T8T1G S-8333ACCA-T8T1G S-8333ACCB-T8T1G S-8333ACCC-T8T1G S-8333ACDA-T8T1G S-8333ACDB-T8T1G S-8333ACDC-T8T1G S-8333ACEA-T8T1G S-8333ACEB-T8T1G S-8333ACEC-T8T1G S-8333ACFA-T8T1G S-8333ACFB-T8T1G S-8333ACFC-T8T1G S-8333ACGA-T8T1G S-8333ACGB-T8T1G S-8333ACGC-T8T1G S-8333ACHA-T8T1G S-8333ACHB-T8T1G S-8333ACHC-T8T1G S-8333ACIA-T8T1G S-8333ACIB-T8T1G S-8333ACIC-T8T1G Seiko Instruments Inc. (5) A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A Function code (6) (7) B E B F B F B F B G B G B G B H B H B H B I B I B I C A C A C A C B C B C B C C C C C C C D C D C D C E C E C E C F C F C F C G C G C G C H C H C H C I C I C I (8) C A B C A B C A B C A B C A B C A B C A B C A B C A B C A B C A B C A B C A B C 35 1.97±0.03 8 7 6 5 3 4 +0.05 1 0.5 2 0.08 -0.02 0.48±0.02 0.2±0.05 No. PH008-A-P-SD-2.0 TITLE SNT-8A-A-PKG Dimensions PH008-A-P-SD-2.0 No. SCALE UNIT mm Seiko Instruments Inc. +0.1 ø1.5 -0 5° 2.25±0.05 4.0±0.1 2.0±0.05 ø0.5±0.1 0.25±0.05 0.65±0.05 4.0±0.1 4 321 5 6 78 Feed direction No. PH008-A-C-SD-1.0 TITLE SNT-8A-A-Carrier Tape PH008-A-C-SD-1.0 No. SCALE UNIT mm Seiko Instruments Inc. 12.5max. 9.0±0.3 Enlarged drawing in the central part ø13±0.2 (60°) (60°) No. PH008-A-R-SD-1.0 TITLE SNT-8A-A-Reel No. PH008-A-R-SD-1.0 SCALE UNIT QTY. mm Seiko Instruments Inc. 5,000 0.52 2.01 0.52 0.3 0.2 0.3 0.2 0.3 0.2 0.3 Caution Making the wire pattern under the package is possible. However, note that the package may be upraised due to the thickness made by the silk screen printing and of a solder resist on the pattern because this package does not have the standoff. No. PH008-A-L-SD-3.0 TITLE SNT-8A-A-Land Recommendation PH008-A-L-SD-3.0 No. SCALE UNIT mm Seiko Instruments Inc. +0.3 3.00 -0.2 8 5 1 4 0.17±0.05 0.2±0.1 0.65 No. FT008-A-P-SD-1.1 TITLE TSSOP8-E-PKG Dimensions FT008-A-P-SD-1.1 No. SCALE UNIT mm Seiko Instruments Inc. 4.0±0.1 2.0±0.05 ø1.55±0.05 0.3±0.05 +0.1 8.0±0.1 ø1.55 -0.05 (4.4) +0.4 6.6 -0.2 1 8 4 5 Feed direction No. FT008-E-C-SD-1.0 TITLE TSSOP8-E-Carrier Tape FT008-E-C-SD-1.0 No. SCALE UNIT mm Seiko Instruments Inc. 13.4±1.0 17.5±1.0 Enlarged drawing in the central part ø21±0.8 2±0.5 ø13±0.5 No. FT008-E-R-SD-1.0 TSSOP8-E-Reel TITLE No. FT008-E-R-SD-1.0 SCALE QTY. UNIT mm Seiko Instruments Inc. 3,000 • • • • • • The information described herein is subject to change without notice. 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The products described herein cannot be used as part of any device or equipment affecting the human body, such as exercise equipment, medical equipment, security systems, gas equipment, or any apparatus installed in airplanes and other vehicles, without prior written permission of Seiko Instruments Inc. Although Seiko Instruments Inc. exerts the greatest possible effort to ensure high quality and reliability, the failure or malfunction of semiconductor products may occur. The user of these products should therefore give thorough consideration to safety design, including redundancy, fire-prevention measures, and malfunction prevention, to prevent any accidents, fires, or community damage that may ensue.