SI9169BQ-T1-E3

Product is End of Life 12/2014 Si9169 Vishay Siliconix High Frequency 1-A Synchronous Buck/Boost Converter DESCRIPTION FEATURES The Si9169 provides fully integrated synchronous buck or boost converter solution for the latest one cell Lithium Ion cellular phones. Capable of delivering up to 1 A of output current at + 3.6 V, the Si9169 provides ample power for various baseband circuits as well as for some PAs. It combines the 2 MHz switching controller with fully integrated high-frequency MOSFETs to deliver the smallest and most efficient converter available today. The 2 MHz switching frequency reduces the inductor height to new level of 2 mm and minimizes the output capacitance requirement to less than 10 µF with peak-to-peak output ripple as low as 10 mV. Combined with low-gate charge high-frequency MOSFETs, the Si9169 delivers efficiency up to 95 %. The programmable pulse skipping mode maintains this high efficiency even during the standby and idle modes to increase overall battery life and talktime. In order to extract the last ounce of power from the battery, the Si9169 is designed with 100 % duty cycle control for buck mode. With 100 % duty cycle, the Si9169 operates like a saturated linear regulator to deliver the highest potential output voltage for longer talktime. • • • • • • • • Voltage Mode Control Fully Integrated MOSFET Switches RoHS 2.7 V to 6 V Input Voltage Range COMPLIANT Programmable PWM/PSM Control - Up to 1 A Output Current at 3.6 V in PWM - Up to 2 MHz Adjustable Switching Frequency in PWM - Less than 200 µA Quiescent Current in PSM Integrated UVLO and POR Integrated Soft-Start Synchronization Shutdown Current < 1 µA Si9169 can be a drop-in replacement of Si9165 provided Pin 1 is not connected. For full 1 A load condition, Pin 1 is required to be connected to low power controller ground. The Si9169 is available in lead (Pb)-free TSSOP-20 pin package. In order to satisfy the stringent ambient temperature requirements, the Si9169 is rated to handle the industrial temperature range of - 25 °C to 85 °C and - 40 °C to 85 °C. FUNCTIONAL BLOCK DIAGRAM INPUT 2.7 to 6 V OUTPUT 0 to 1 A INPUT 2.7 to 6 V COIL VO VDD MODE VS VIN/OUT FB VDD PGND MODE SYNC PGND ROSC REF GND Boost Configuration Document Number: 70945 S-72058-Rev. E, 08-Oct-07 FB COMP SHUTDOWN COMP PWM/PSM OUTPUT 0 to 1 A COIL VS VIN/OUT VO SHUTDOWN ROSC PWM/PSM REF SYNC PGND GND Buck Configuration www.vishay.com 1 Si9169 Vishay Siliconix ABSOLUTE MAXIMUM RATINGS Parameter Voltages Referenced to GND VDD MODE PWM/PSM, SYNC, SD, VREF, ROSC, COMP, FB VO PGND Voltages Referenced to PGND VS, VIN/OUT COIL Peak Output Current Continuous Output Current Storage Temperature Range Operating Junction Temperature Power Dissipation (Package)a 20-Pin TSSOP (Q Suffix)b Thermal Impedance (ΘJA) 20-Pin TSSOPc Notes: a. Device Mounted with all leads soldered or welded to PC board. b. Derate 11 mW/°C above 60 °C. c. With Pin 1 connected to GND plane. Limit Unit 6.5 - 0.3 V to VDD + 0.3 V - 0.3 V to VS + 0.3 V ± 0.3 V 6.5 - 0.4 V to VIN/OUT + 0.4 V 3 A for 1 ms 1.4 - 65 to 150 150 1.0 90 V A °C W °C/W Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. RECOMMENDED OPERATING CONDITIONS Parameter Voltages Referenced to GND VDD MODE, PWM/PSM, SYNC, SD Voltages Referenced to PGND VS, VIN/OUT FOSC ROSC VREF Capacitor Limit Unit 2.7 V to 6 V V 0 V to VDD V 2.7 V to 6 V 200 kHz to 2 MHz 25 kΩ to 300 kΩ 0.1 V kΩ µF SPECIFICATIONS Parameter Symbol Test Conditions Unless Otherwise Specified 2.7 V < VDD < 6 V, VIN/OUT = 3.3 V, VS = 3.3 V Mina Typb Maxa IREF = 0 A 1.265 1.3 1.330 TA = 25 °C, IREF = 0 1.280 1.3 1.320 Limitse Unit Reference Output Voltage VREF Load Regulation ΔVREF Power Supply Rejection PSRR VDD = 3.3 V, - 500 µA < IREF < 0 V 3 mV 60 dB UVLO Under Voltage Lockout (turn-on) Hysteresis VUVLO/LH VHYS 2.3 VUVLOLH - VUVLOHL 2.4 2.5 0.1 V Soft-Start Time SS Time tSS 6 ms Mode Logic High VIH Logic Low VIL Input Current www.vishay.com 2 IL 0.7 VDD 0.3 VDD - 1.0 1.0 V µA Document Number: 70945 S-72058-Rev. E, 08-Oct-07 Si9169 Vishay Siliconix SPECIFICATIONS Parameter Symbol Test Conditions Unless Otherwise Specified 2.7 V < VDD < 6 V, VIN/OUT = 3.3 V, VS = 3.3 V Limitse Mina Typb Maxa Unit SD, SYNC, PWM/PSM Logic High VIH Logic Low VIL 2.4 0.8 IL Input Current - 1.0 1.0 V µA Oscillator FMAX Maximum Frequency 2 Nominal 1.60 MHz, ROSC = 30 kΩ Accuracy Maximum Duty Cycle (Buck, Non LDO Mode) DMAX FSW = 2 MHz Maximum Duty Cycle (Boost) 20 Si9169BQ 75 85 Si9169DQ 73 85 Si9169BQ 52 65 Si9169DQ 50 65 FSYNC/FOSC SYNC Range MHz - 20 1.2 SYNC Low Pulse Width 50 SYNC High Pulse Width 50 % 1.5 ns SYNC tr, tf 50 Error Amplifier Input Bias Current IBIAS Open Loop Voltage Gain AVOL FB Threshold VFB Unity Gain BW BW IEA Output Current VFB = 1.5 V -1 50 60 TA = 25 °C 1.270 1.30 1.330 1.255 1.30 1.340 1 dB 2 Source (VFB = 1.05 V), VCOMP = 0.75 V -3 Sink (VFB = 1.55 V), VCOMP = 0.75 V 1 VOUT ≤ 4.2 V 1000 µA V MHz -1 3 mA Output Current Output Current (PWM) Output Current (PSM) Boost Modec Buck Moded Boost Mode c IOUT Buck Moded rDS(on) N-Channel rDS(on) P-Channel rDS(on) 1.8 V ≤ VOUT ≤ 5.0 V 1000 VIN = 3.3 V, VOUT = 3.6 V 150 VIN = 3.6 V, VOUT = 2.7 V 150 VS ≥ 3.3 V mA 130 300 160 330 mΩ Over Temperature Protection Trip Point Rising Temperature Hysteresis 165 °C 25 Supply Normal Mode PSM Mode Shutdown Mode IDD VDD = 3.3 V, FOSC = 2 MHz 500 750 VDD = 3.3 V 180 250 VDD = 3.3 V, SD = 0 V µA 1 Notes: a. The algebraic convention whereby the most negative value is a minimum and the most positive a maximum. b. Typical values are for DESIGN AID ONLY, not guaranteed nor subject to production testing. c. VIN = VDD, VOUT = VIN/OUT = VS = VO, L = 1.5 µH, VIN ≤ VOUT d. VIN = VDD = VS = VIN/OUT, VOUT = VO, L = 1.5 µH, VIN ≥ VOUT e. Limits are for both Si9169BQ (- 25 °C to 85 °C) and Si9169DQ (- 40 °C to 85 °C) unless otherwise noted. Document Number: 70945 S-72058-Rev. E, 08-Oct-07 www.vishay.com 3 Si9169 Vishay Siliconix 1.310 1.32 1.305 1.31 V REF (V) V REF (V) TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted 1.300 1.295 1.30 1.29 1.290 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 1.28 - 50 6.0 0 50 VDD - (V) 100 150 Temperature (° C) VREF vs. VDD VREF vs. Temperature 10000 2.00 1.95 1.90 Frequency (kHz) Frequency (MHz) ROSC = 25 kΩ 1.85 1.80 1000 1.75 1.70 - 100 100 - 50 0 50 100 150 10 100 Temperature (° C) ROSC (kΩ) Frequency vs. Temperature Frequency vs. ROSC 100 95 PSM- 3 V 90 90 PSM- 3.6 V 85 85 PSM- 4.2 V PWM- 3 V 80 PWM- 3.6 V 75 PWM- 2.7 V PSM- 2.7 V 80 75 70 PWM- 4.2 V 70 PWM- 3.3 V PSM- 3.3 V Efficiency (%) Efficiency (%) 95 1000 65 65 60 60 1 10 100 Load Current (mA) Buck Mode Efficiency, VO = 2.7 V www.vishay.com 4 1000 1 10 100 1000 Load Current (mA) Boost Mode Efficiency, VO = 3.6 V Document Number: 70945 S-72058-Rev. E, 08-Oct-07 Si9169 Vishay Siliconix TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted 800 250 700 200 I DD (µA) I DD (µA) 600 500 150 400 100 300 50 200 2 3 4 5 6 2 7 3 4 5 6 7 VDD - (V) VDD - (V) PSM Supply Current PWM Supply Current PIN CONFIGURATION AND ORDERING INFORMATION TSSOP-20 GND SD PWM/PSM VIN/OUT VIN/OUT VIN/OUT SYNC GND VREF FB 1 2 3 4 5 6 7 8 9 10 Si9169 ORDERING INFORMATION 20 19 18 17 16 15 14 13 12 11 COIL COIL MODE PGND PGND VS VO VDD ROSC COMP Part Number Temperature Range Si9169BQ-T1-E3 - 25 to 85 °C Si9169DQ-T1-E3 - 40 to 85 °C Package Tape and Reel Top View PIN DESCRIPTION Pin Number Name 1 GND 2 3 SD Function Low power controller ground. Can be left unconnected for load currents below 600 mA. Shuts down the IC completely and decreases current consumed by the IC to < 1 µA. PWM/PSM Logic high = PWM mode, logic low = PSM mode. In PSM mode, synchronous rectification is disabled. 4, 5, 6 VIN/OUT 7 SYNC Input node for buck mode and output node for boost mode. Externally controlled synchronization signal. Logic high to low transition forces the clock synchronization. If not used, the pin must be connected to VDD, or logic high. 8 GND Low power controller ground 9 VREF 1.3 V reference. Decoupled with 0.1 µF capacitor. 10 FB 11 COMP 12 Rosc External resistor to determine the switching frequency. 13 VDD Input supply voltage for the analog circuitry. Input voltage range is 2.7 V to 6 V. 14 VO Direct output voltage sensing to control peak inductor current in PSM mode. 15 VS Supply voltage for the internal MOSFET drive circuit. 16, 17 PGND 18 MODE 19, 20 COIL Document Number: 70945 S-72058-Rev. E, 08-Oct-07 Output voltage feedback connected to the inverting input of an error amplifier. Error amplifier output for external compensation network. Power ground. Determines the converter topology. Connect to AGND for buck or VDD for boost. Inductor connection node www.vishay.com 5 Si9169 Vishay Siliconix FUNCTIONAL BLOCK DIAGRAM SD VDD VS VIN/OUT Positive Supply Reference Threshold Generator Soft-Start Timer UVLO POR Bias Generator OTP VREF FB COMP PWM Modulator 1.0 V Ramp P PWMIN PWMEN 0.5 V SYNC PWM/PSM Select Oscillator ROSC PSMEN COSC COIL Drivers N PSMIN PSM Modulator VO PWM/PSM MODE Negative Return and Substrate GND PGND DETAIL OPERATIONAL DESCRIPTION Start-Up The UVLO circuit prevents the internal MOSFET switches and oscillator circuit from turning on, if the voltage on VDD pin is less than 2.5 V. With typical UVLO hysteresis of 0.1 V, controller is continuously powered on until the VDD voltage drops below 2.4 V. This hysteresis prevents the converter from oscillating during the start-up phase and unintentionally locking up the system. Once the VDD voltage exceeds the UVLO threshold, and with no other shutdown condition detected, an internal Power-On-Reset timer is activated while most circuitry, except the output driver, are turned on. After the POR timeout of about 1 ms, the internal soft-start capacitor is allowed to charge. When the soft-start capacitor voltage reaches 0.5 V, the PWM circuit is enabled. Thereafter, the constant current charging the soft-start capacitor will force the output voltage to rise gradually without overshooting. To prevent negative undershoot, the synchronous switch is tri-stated until the duty cycle reaches about 10 %. In tri-state, the high-side P-Channel MOSFET is www.vishay.com 6 turned off by pulling up the gate voltage to VS potential. The low-side N-Channel MOSFET is turned off by pulling down the gate voltage to PGND potential. Note that the Si9169 will always soft starts in the PWM mode regardless of the voltage level on the PWM/PSM pin. Shutdown The Si9169 is designed to conserve as much battery life as possible by decreasing current consumption of IC during normal operation as well as the shutdown mode. With logic low level on the SD pin, current consumption of the Si9169 is decreased to less than 1 µA by shutting off most of the circuits. The logic high enables the controller and starts up as described in "Start-Up" section above. Document Number: 70945 S-72058-Rev. E, 08-Oct-07 Si9169 Vishay Siliconix DETAIL OPERATIONAL DESCRIPTION (CONT’D) Over Temperature Protection The Si9169 is designed with over temperature protection circuit to prevent MOSFET switches from running away. If the temperature reaches 165 °C, internal soft-start capacitor is discharged, shutting down the output stage. Converter remains in the disabled mode until the temperature in the IC decreases below 140 °C. PWM Mode With PWM/PSM mode pin in logic high condition, the Si9169 operates in constant frequency (PWM) mode. As the load and line varies, switching frequency remain constant. The switching frequency is programmed by the Rosc value as shown by the Oscillator curve. In the PWM mode, the synchronous drive is always enabled, even when the output current reaches 0 A to assure the converter is operating in continuous current mode. In continuous current mode, transfer function of the converter remain constant, providing fast transient response. If the converter operates in discontinuous current mode, overall loop gain decreases and transient response time can be ten times longer than if the converter remain in continuous current mode. This transient response time advantage can significantly decrease the hold-up capacitors needed on the output of dc-dc converter to meet the transient voltage regulation. Therefore, the PWM/PSM pin is available to dynamically program the controller. The maximum duty cycle of the Si9169 can reach 100 % in buck mode. This allows the system designers to extract out the maximum stored energy from the battery. Once the controller delivers 100 % duty cycle, converter operates like a saturated linear regulator. At 100 % duty cycle, synchronous rectification is completely turned off. Up to a maximum duty cycle of 80 % at 2 MHz switching frequency, controller maintains perfect output voltage regulation. If the input voltage drops below the level where the converter requires greater than 80 % duty cycle, controller will deliver 100 % duty cycle. This instantaneous jump in duty cycle is due to fixed BBM time, MOSFET delay/rise/fall time, and the internal propagational delays. In order to maintain regulation, controller might fluctuate its duty cycle back and forth from 100 % to something less than maximum duty cycle while the converter is operating in this input voltage range. If the input voltage drops further, controller will remain on 100 %. If the input voltage increases to a point where it requires less than 80 % duty cycle, synchronous rectification is once again activated. The maximum duty cycle under boost mode is internally limited to 75 % to prevent inductor saturation. If the converter is turned on for 100 % duty cycle, inductor never gets a chance to discharge its energy and eventually saturates. Document Number: 70945 S-72058-Rev. E, 08-Oct-07 In boost mode, synchronous rectifier is always turned on for minimum or greater duration as long as the switch has been turned on. The controller will deliver 0 % duty cycle, if the input voltage is greater than the programmed output voltage. Because of signal propagation time and MOSFET delay/rise/ fall time, controller will not transition smoothly from minimum controllable duty cycle to 0 % duty cycle. For example, controller may decrease its duty cycle from 5 % to 0 % abruptly, instead of gradual decrease you see from 75 % to 5 %. Pulse Skipping Mode The gate charge losses produced from the Miller capacitance of MOSFETs are the dominant power dissipation parameter during light load (i.e. < 10 mA). Therefore, less gate switching will improve overall converter efficiency. This is exactly why the Si9169 is designed with pulse skipping mode. If the PWM/PSM pin is connected to logic low level, converter operates in pulse skipping modulation (PSM) mode. During the pulse skipping mode, quiescent current of the controller is decreased to approximately 200 µA, instead of 500 µA during the PWM mode. This is accomplished by turning off most of internal control circuitry and utilizing a simple constant on-time control with feedback comparator. The controller is designed to have a constant on-time and a minimum off-time acting as the feedback comparator blanking time. If the output voltage drops below the desired level, the main switch is first turned on and then off. If the applied on-time is insufficient to provide the desired voltage, the controller will force another on and off sequence, until the desired voltage is accomplished. If the applied on-time forces the output to exceed the desired level, as typically found in the light load condition, the converter stays off. The excess energy is delivered to the output slowly, forcing the converter to skip pulses as needed to maintain regulation. The on-time and off-time are set internally based on inductor used (1.5 µH typical), mode pin selection and maximum load current. Wide duty cycle range can be achieved in both buck and boost configurations. In pulse skipping mode, synchronous rectifier drive is also disabled to further decrease the gate charge loss, which in turn improves overall converter efficiency. Reference The reference voltage of the Si9169 is set at 1.3 V. The reference voltage is internally connected to the non-inverting inputs of the error amplifier. The reference is decoupled with 0.1 µF capacitor. www.vishay.com 7 Si9169 Vishay Siliconix DETAIL OPERATIONAL DESCRIPTION (CONT’D) Error Amplifier Break-Before-Make Timing The error amplifier gain-bandwidth product and slew rate is critical parameters which determines the transient response of converter. The transient response is function of both small and large signal response. The small signal is the converter closed loop bandwidth and phase margin while the large signal is determined by the error amplifier dv/dt and the inductor di/dt slew rate. Besides the inductance value, error amplifier determines the converter response time. In order to minimize the response time, the Si9169 is designed with 2 MHz error amplifier gain-bandwidth product to generate the widest converter bandwidth and 3.5 V/µs slew rate for ultrafast large signal response. A proper BBM time is essential in order to prevent shootthrough current and maintain high efficiency. The breakbefore-make time is set internally at 20 ns at VS = 3.6 V. The high and low-side MOSFET drain voltages are monitored and when the drain voltage reaches the 1.75 V below or above its initial starting voltage, 20 ns BBM time is set before the other switch turns on. The maximum controllable duty cycle is limited by the BBM time. Since the BBM time is fixed, maximum controllable duty cycle will vary depending on the switching frequency. Oscillator The high- and low-side switches are integrated to provide optimum performance and to minimize the overall converter size. Both, high and low-side switches are designed to handle up to 1 A of continuous current. The MOSFET switches were designed to minimize the gate charge loss as well as the conduction loss. For the high frequency operation, switching losses can exceed conduction loss, if the switches are designed incorrectly. Under full load, efficiency of 90 % is accomplished with 3.6 V battery voltage in both buck and boost modes (+ 2.7 V output voltage for buck mode and + 5 V output voltage for boost mode). The oscillator is designed to operate up to 2 MHz minimal. The 2 MHz operating frequency allows the converter to minimize the inductor and capacitor size, improving the power density of the converter. Even with 2 MHz switching frequency, quiescent current is only 500 µA with unique power saving circuit design. The switching frequency is easily programmed by attaching a resistor to ROSC pin. See oscillator frequency versus ROSC curve to select the proper values for desired operating frequency. The tolerance on the operating frequency is ± 20 % with 1 % tolerance resistor. Output MOSFET Stage Synchronization The synchronization to external clock is easily accomplished by connecting the external clock into the SYNC pin. A logic high to low transition synchronizes the clock. The external clock frequency must be within 1.2 to 1.5 times the internal clock frequency. Vishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, and reliability data, see http://www.vishay.com/ppg?70945. www.vishay.com 8 Document Number: 70945 S-72058-Rev. E, 08-Oct-07 Package Information Vishay Siliconix TSSOP: 20-LEAD (POWER IC ONLY) B D 4X N 0.20 C A−B D 0.20 H A−B D 2X N/2 TIPS E1 E bbb 1.00 b M C A−B A2 E/2 D 9
0.05 C A 1 2 3 1.00 DIA. aaa H A1 e 1.00 C C SEATING PLANE A D (14_) SIDE VIEW MILLIMETERS 0.25 PARTING LINE + + H L (∝) 6 c 1.00 B B (14_) DETAIL ‘A’ (SCALE: 30/1) (VIEW ROTATED 90_ C.W.) C L e/2 X X = A and B LEAD SIDES TOP VIEW Document Number: 72818 28-Jan-04 SEE DETAIL ‘A’ Dim A A1 A2 aaa b b1 bbb c c1 D E E1 e L N P P1 ∝ Min Nom Max — — 1.10 0.05 — 0.15 0.85 0.90 0.95 0.076 0.19 − 0.30 0.19 0.22 0.25 0.10 0.09 0.09 − 0.20 0.127 0.16 6.50 BSC 6.40 BSC 4.30 4.40 4.50 0.65 BSC 0.50 0.60 0.70 20 4.2 3.0 0_ — 8_ ECN: S-40082—Rev. A, 02-Feb-04 DWG: 5923 END VIEW www.vishay.com 1 Legal Disclaimer Notice www.vishay.com Vishay Disclaimer ALL PRODUCT, PRODUCT SPECIFICATIONS AND DATA ARE SUBJECT TO CHANGE WITHOUT NOTICE TO IMPROVE RELIABILITY, FUNCTION OR DESIGN OR OTHERWISE. Vishay Intertechnology, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf (collectively, “Vishay”), disclaim any and all liability for any errors, inaccuracies or incompleteness contained in any datasheet or in any other disclosure relating to any product. Vishay makes no warranty, representation or guarantee regarding the suitability of the products for any particular purpose or the continuing production of any product. To the maximum extent permitted by applicable law, Vishay disclaims (i) any and all liability arising out of the application or use of any product, (ii) any and all liability, including without limitation special, consequential or incidental damages, and (iii) any and all implied warranties, including warranties of fitness for particular purpose, non-infringement and merchantability. Statements regarding the suitability of products for certain types of applications are based on Vishay's knowledge of typical requirements that are often placed on Vishay products in generic applications. Such statements are not binding statements about the suitability of products for a particular application. It is the customer's responsibility to validate that a particular product with the properties described in the product specification is suitable for use in a particular application. Parameters provided in datasheets and / or specifications may vary in different applications and performance may vary over time. All operating parameters, including typical parameters, must be validated for each customer application by the customer's technical experts. Product specifications do not expand or otherwise modify Vishay's terms and conditions of purchase, including but not limited to the warranty expressed therein. Hyperlinks included in this datasheet may direct users to third-party websites. These links are provided as a convenience and for informational purposes only. Inclusion of these hyperlinks does not constitute an endorsement or an approval by Vishay of any of the products, services or opinions of the corporation, organization or individual associated with the third-party website. Vishay disclaims any and all liability and bears no responsibility for the accuracy, legality or content of the third-party website or for that of subsequent links. Except as expressly indicated in writing, Vishay products are not designed for use in medical, life-saving, or life-sustaining applications or for any other application in which the failure of the Vishay product could result in personal injury or death. Customers using or selling Vishay products not expressly indicated for use in such applications do so at their own risk. Please contact authorized Vishay personnel to obtain written terms and conditions regarding products designed for such applications. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay. Product names and markings noted herein may be trademarks of their respective owners. © 2022 VISHAY INTERTECHNOLOGY, INC. ALL RIGHTS RESERVED Revision: 01-Jan-2022 1 Document Number: 91000