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DA9313-03VK2

DA9313-03VK2

  • 厂商:

    DIALOGSEMICONDUCTOR(戴乐格)

  • 封装:

    UFBGA43

  • 描述:

    IC BAT PWR MGT LI-ION 2C 43WLCSP

  • 数据手册
  • 价格&库存
DA9313-03VK2 数据手册
DA9313 High Efficiency Dual Cell Switched Capacitor Divider General Description DA9313 is a high-voltage power converter with a maximum output current of 10 A, suitable for applications supplied from a dual (2S) Li-ion or Li-polymer stacked cell battery pack, or any input voltage between 5 V and 10.5 V. The converter operates with efficiency during conversion of up to 98 %. Master/slave operation is offered, where a pair of devices can combine to double the peak output current to 20 A. Low profile external components and a minimum PCB footprint allow small circuit implementation in compact applications. The pass devices are fully integrated therefore no external FETs are needed. DA9313 utilizes a programmable soft start to limit the inrush current from the input node and secure a slope controlled activation of the rails. It also implements integrated over-temperature and overcurrent protection for increased system reliability without the need for external sensing components. Enable, low power mode entry and exit, and power good signals are available at configurable ports flexibly supporting different applications and power-up or power-down scenarios. Key Features ■ 2S to 1S power voltage converter ■ VOUT = ½ VIN ■ 5 V to 10.5 V input voltage (2S Li-ion stacked ■ High and flat efficiency, up to 98 % battery pack) ■ Typical 55 μA quiescent current (standalone) ■ 10 A total output current (standalone) □ Typical 70 μA total quiescent current in ■ 20 A total output current (master/slave) master/slave configuration ■ 1.0 mm max external components height ■ Package 43 WLCSP (RouteEasy™ equivalent to 0.65 mm pitch) ■ Integrated power switches ■ I2C compatible interface Applications ■ ■ ■ ■ ■ Ultrabooks™ Notebook computers Chromebooks™ Tablets ■ ■ ■ ■ DSLR and mirrorless cameras Camcorders Power banks 2S battery applications Smartphone direct charging Datasheet CFR0011-120-00 Revision 3.3 1 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Contents General Description ............................................................................................................................ 1 Key Features ........................................................................................................................................ 1 Applications ......................................................................................................................................... 1 Contents ............................................................................................................................................... 2 Figures .................................................................................................................................................. 3 Tables ................................................................................................................................................... 4 1 Terms and Definitions ................................................................................................................... 5 2 References ..................................................................................................................................... 5 3 Functional Block Diagrams .......................................................................................................... 6 4 Pinout ........................................................................................................................................... 10 5 Absolute Maximum Ratings ....................................................................................................... 12 6 Recommended Operating Conditions ....................................................................................... 12 7 Electrical Characteristics ........................................................................................................... 13 7.1 Power-On-Reset, Reference Generation and Supervision ................................................. 13 7.2 Internal Oscillator ................................................................................................................ 14 7.3 Power Voltage Converter .................................................................................................... 14 7.4 VCORE................................................................................................................................ 15 7.5 VDDIO ................................................................................................................................. 16 7.6 Digital I/O Characteristics.................................................................................................... 16 8 I2C Control Bus ............................................................................................................................ 18 9 Typical Characteristics ............................................................................................................... 19 9.1 Standalone Operation ......................................................................................................... 19 9.2 Master/Slave Operation ...................................................................................................... 20 10 Functional Description ............................................................................................................... 22 10.1 Start Up 22 10.1.1 Standalone Operation .......................................................................................... 22 10.1.2 Master/Slave Operation ....................................................................................... 22 10.2 Interface Functions .............................................................................................................. 23 10.2.1 GPIOs .................................................................................................................. 23 10.2.2 nONKEY .............................................................................................................. 25 10.3 Power Voltage Converter .................................................................................................... 27 10.3.1 PVC Output Voltage ............................................................................................ 27 10.3.2 PVC Start-Up ....................................................................................................... 27 10.3.3 PVC Operating Modes ......................................................................................... 28 10.3.4 PVC Power Down ................................................................................................ 29 10.3.5 PVC Current Limit ................................................................................................ 29 11 Operating Modes ......................................................................................................................... 30 11.1 OFF Mode (HARDRESET) ................................................................................................. 31 11.2 POWER_DOWN Mode ....................................................................................................... 31 11.3 ACTIVE Mode ..................................................................................................................... 31 11.4 SLEEP Mode ....................................................................................................................... 31 11.5 FAULT RECOVERY Mode.................................................................................................. 32 Datasheet CFR0011-120-00 Revision 3.3 2 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 11.5.1 Input Under-Voltage............................................................................................. 32 11.5.2 Over-Temperature ............................................................................................... 33 11.5.3 PVC Current Limit ................................................................................................ 33 11.5.4 PVC Start-Up Failure ........................................................................................... 33 11.6 VCORE Voltage Regulator ................................................................................................. 33 11.7 VDDIO Generation .............................................................................................................. 33 11.8 Internal Oscillator ................................................................................................................ 34 11.8.1 Internal Temperature Supervision ....................................................................... 34 12 Control Interface .......................................................................................................................... 35 12.1 I2C Communication ............................................................................................................. 35 12.2 I2C Control Bus Protocol ..................................................................................................... 35 13 Register Definitions .................................................................................................................... 38 14 Package Information ................................................................................................................... 50 14.1 Package Outline .................................................................................................................. 50 14.2 Moisture Sensitivity Level.................................................................................................... 51 14.3 WLCSP Handling ................................................................................................................ 51 14.4 Soldering Information .......................................................................................................... 51 15 Layout Guidelines ....................................................................................................................... 52 15.1 Suggested PCB Layout ....................................................................................................... 52 15.2 RouteEasyTM Technology Chart ........................................................................................ 52 16 Application Information .............................................................................................................. 53 16.1 Recommended Capacitors ................................................................................................. 53 17 Ordering Information .................................................................................................................. 53 Figures Figure 1: Functional Block Diagram Standalone (I2C Not Connected) ................................................. 6 Figure 2: Functional Block Diagram Master/Slave Operation (I 2C Not Connected) .............................. 7 Figure 3: Functional Block Diagram Standalone (I2C Connected) ........................................................ 8 Figure 4: Functional Block Diagram Master/Slave Operation (I 2C Connected) .................................... 9 Figure 5: Connection Diagram ............................................................................................................ 10 Figure 6: I2C Bus Timing ..................................................................................................................... 18 Figure 7: DA9313 Efficiency Automatic Mode Standalone ................................................................. 19 Figure 8: DA9313 Efficiency Fixed Frequency Mode Standalone....................................................... 19 Figure 9: DA9313 Output Voltage Drop Automatic Mode Standalone ................................................ 20 Figure 10: DA9313 Efficiency Automatic Mode Master/Slave ............................................................. 20 Figure 11: DA9313 Efficiency Fixed Frequency Mode Master/Slave .................................................. 21 Figure 12: DA9313 Output Voltage Drop Automatic Mode Master/Slave ........................................... 21 Figure 13: Master Slave Timing in Automatic Frequency Mode ......................................................... 28 Figure 14: Operating Modes ................................................................................................................ 30 Figure 15: Timing of I2C START and STOP Condition ........................................................................ 36 Figure 16: I2C Byte Write (SDA Line) .................................................................................................. 36 Figure 17: I2C Byte Read (SDA Line) .................................................................................................. 36 Figure 18: I2C Page Read (SDA Line) ................................................................................................. 37 Figure 19: I2C Page Write (SDA Line) ................................................................................................. 37 Figure 20: I2C Repeated Write (SDA Line) .......................................................................................... 37 Figure 21: 43 WLCSP Package Outline Drawing ................................................................................ 50 Figure 22: Suggested PCB Layout ...................................................................................................... 52 Datasheet CFR0011-120-00 Revision 3.3 3 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Tables Table 1: Pin Description ...................................................................................................................... 10 Table 2: Pin Type Definition ................................................................................................................ 11 Table 3: Absolute Maximum Ratings ................................................................................................... 12 Table 4: Recommended Operating Conditions ................................................................................... 12 Table 5: Power-on-Reset, Reference and Supervision Characteristics .............................................. 13 Table 6: Internal Oscillator Characteristics .......................................................................................... 14 Table 7: Power Voltage Converter Characteristics ............................................................................. 14 Table 8: VCORE Characteristics ......................................................................................................... 15 Table 9: VDDIO Characteristics .......................................................................................................... 16 Table 10: Digital I/O Characteristics .................................................................................................... 16 Table 11: I2C Control Bus Characteristics ........................................................................................... 18 Table 12: GPIO Configuration Overview ............................................................................................. 23 Table 13: SLEEP_CTRL Register Configuration ................................................................................ 31 Table 14: Register Map ....................................................................................................................... 38 Table 15: VENDORID 0x01 ................................................................................................................. 38 Table 16: MODE_CTRL 0x02 ............................................................................................................. 39 Table 17: SLEEP_CTRL 0x03 ............................................................................................................. 39 Table 18: PVC_CTRL 0x04 ................................................................................................................. 40 Table 19: GPIO_CTRL 0x05 ............................................................................................................... 40 Table 20: GPIO_CTRL_2 0x06 ........................................................................................................... 41 Table 21: INTERFACE_CTRL 0x07 .................................................................................................... 42 Table 22: NONKEY_CTRL 0x08 ......................................................................................................... 42 Table 23: MASK 0x09.......................................................................................................................... 43 Table 24: STATUS 0x0A ..................................................................................................................... 43 Table 25: EVENT 0x0B ....................................................................................................................... 44 Table 26: FAULT_LOG 0x0C .............................................................................................................. 44 Table 27: LOCK_REG 0x0D................................................................................................................ 44 Table 28: PVC_CONFIG_1 0x0E ........................................................................................................ 45 Table 29: PVC_CONFIG_2 0x0F ........................................................................................................ 45 Table 30: PVC_CONFIG_3 0X10 ........................................................................................................ 46 Table 31: CONFIG_A 0x11 ................................................................................................................. 47 Table 32: CONFIG_C 0x13 ................................................................................................................. 47 Table 33: CONFIG_D 0x14 ................................................................................................................. 48 Table 34: VARIANT_ID 0x30............................................................................................................... 48 Table 35: DEVICE_ID 0x31 ................................................................................................................. 48 Table 36: CUSTOMER_ID 0x32 ......................................................................................................... 48 Table 37: CONFIG_ID 0x33 ................................................................................................................ 49 Table 38: MSL Classification ............................................................................................................... 51 Table 39: Recommended Capacitor Types ......................................................................................... 53 Table 40: Ordering Information ........................................................................................................... 53 Datasheet CFR0011-120-00 Revision 3.3 4 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 1 Terms and Definitions CCM DCM HBM OTP PCB PG PMIC POR PVC PWC 2 [1] Continuous Conduction Mode Discontinuous Conduction Mode Human Body Model One Time Programmable Printed Circuit Board Power Good Power Management Integrated Circuit Power On Reset Power Voltage Converter Power Cycle References UM10204 I2C Bus Specification and User Manual Datasheet CFR0011-120-00 Revision 3.3 5 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 3 Functional Block Diagrams CBS_PVC CFLY BS1 C1P CFLY C2N C1N CBS_PVC C2P BS2 VBAT VBAT (2S) VOUT_S VIN VOUT Power Voltage Converter CIN_PVC CO_PVC VBAT/2 (1S) CLOAD PGND DA9313 nONKEY/IC_EN VCORE ON/OFF CTRL PWC/PVC_EN/SLEEP_EN/ GPIO_1 PG/nIRQ/Ext_Clk_Inp/SLAVE_ID PWC/PVC_EN/SLEEP_EN/ PG/nIRQ/MS_IF Digital Core CO_VCORE OTP IN/OUT GPIO_0 IN/OUT Bias, Supervision, Oscillator AGND SCL SDA Figure 1: Functional Block Diagram Standalone (I2C Not Connected) Datasheet CFR0011-120-00 Revision 3.3 6 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider CBS_PVC BS1 C1P CFLY CFLY CBS_PVC C1N C2N C2P BS2 VBAT VBAT (2S) VIN VOUT_S CIN_PVC VBAT/2 (1S) VOUT Power Voltage Converter CLOAD CO_PVC PGND SLAVE nONKEY/IC_EN nONKEY PWC/PVC_EN/SLEEP_EN/ PG/nIRQ/Ext_Clk_Inp/SLAVE_ID DA9313 VCORE ON/OFF CTRL CBS_PVC CFLY CFLY CBS_PVC CO_VCORE GPIO_1 IN/OUT Digital core BS1 OTP C1P C1N C2N BS2 C2P VBAT GPIO_0 AGND Bias, Supervision, Oscillator MS_IF OUT VOUT_S VIN CIN_PVC VOUT Power Voltage Converter SCL SDA CO_PVC PGND MASTER NC nONKEY VCORE GPIO_1 DA9313 VCORE ON/OFF CTRL IN/OUT Digital core CO_VCORE OTP GPIO_0 IN AGND Bias, Supervision, Oscillator SCL SDA Figure 2: Functional Block Diagram Master/Slave Operation (I2C Not Connected) Datasheet CFR0011-120-00 Revision 3.3 7 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider CBS_PVC BS1 C1P CFLY C1N CFLY CBS_PVC C2N C2P BS2 VBAT VBAT (2S) VOUT_S VIN CIN_PVC VOUT Power Voltage Converter VBAT/2 (1S) CO_PVC CLOAD PGND nONKEY/IC_EN VCORE DA9313 ON/OFF CTRL CO_VCORE PWC/PVC_EN/SLEEP_EN/ GPIO_1 PG/nIRQ/Ext_Clk_Inp/SLAVE_ID Digital Core OTP Memory Bias, Supervision, Oscillator Register Space IN/OUT GPIO_0 PWC/PVC_EN/SLEEP_EN/ PG/nIRQ/MS_IF IN/OUT AGND SCL INOUT IN 2-Wire Interface SDA SCL SDA Figure 3: Functional Block Diagram Standalone (I2C Connected) Datasheet CFR0011-120-00 Revision 3.3 8 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider CBS_PVC BS1 C1P Cfly Cfly C2N C1N CBS_PVC C2P BS2 VBAT VBAT (2S) VOUT_S VIN CIN_PVC VOUT Power Voltage Converter VBAT/2 (1S) Co_pvc PGND nONKEY/IC_EN VCORE DA9313 nONKEY ON/OFF CTRL PWC/PVC_EN/SLEEP_EN/PG/nIRQ/ Ext_Clk_Inp/SLAVE_ID GPIO_1 CLOAD SLAVE CBS_PVC Cfly Co_vcore Digital Core OTP Memory BS1 C1P IN/OUT GPIO_0 Register Space C2N C1N C2P BS2 VOUT_S VIN MS_IF Bias, Supervision, Oscillator CBS_PVC VBAT AGND OUT Cfly CIN IN INOUT SCL VOUT Power Voltage Converter 2-Wire Interface CO_PVC PGND SDA VCORE DA9313 NC nONKEY MASTER VCORE ON/OFF CTRL GPIO_1 Digital Core OTP Memory CO_VCORE Bias, Supervision, Oscillator Register Space AGND IN/OUT GPIO_0 IN SCL SDA SCL INOUT IN 2-Wire Interface SDA Figure 4: Functional Block Diagram Master/Slave Operation (I2C Connected) Datasheet CFR0011-120-00 Revision 3.3 9 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 4 Pinout 1 2 3 4 5 6 7 8 9 10 11 12 A VIN C1P C1P BS1 C1N C1N B VIN C1P VOUT VOUT C1N PGND C nONKEY VIN VOUT VOUT VOUT PGND D SCL VCORE E GPIO_0 AGND F SDA VOUT_S VBAT G GPIO_1 VIN VOUT VOUT VOUT PGND H VIN C2P VOUT VOUT C2N PGND J VIN C2P C2P BS2 C2N C2N Top View Power supply Analog signal Digital signal Ground Figure 5: Connection Diagram Table 1: Pin Description Location Pin Name Pin Type (Table 2) F12 VBAT AI/P VBAT input for voltage supervision and supply input voltage for power voltage converter controller A1, B2, C3 J1, H2, G3 VIN PWR Supply input voltage for power path A3, B4, A5 C1P AIO Flying capacitance 1 positive terminal A9, B10, A11 C1N AIO Flying capacitance 1 negative terminal A7 BS1 AIO Boot strap capacitor positive terminal for power voltage converter J3, H4, J5 C2P AIO Flying capacitance 2 positive terminal J9, H10, J11 C2N AIO Flying capacitance 2 negative terminal J7 BS2 AIO Boot strap capacitor positive terminal for power voltage converter B6, B8, C5, C7, C9, G5, G7,G9, H6, H8 VOUT AO Power voltage converter output voltage Datasheet CFR0011-120-00 Description Revision 3.3 10 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Location Pin Name Pin Type (Table 2) Description F10 VOUT_S AI Power voltage converter output sense D12 VCORE AIO Main internal supply C1 nONKEY AIO On key signal (active low) E1 GPIO_0 DIO General purpose input/output G1 GPIO_1 DIO General purpose input/output F2 SDA DIO I2C data. Must be connected to GND if no I2C interface D2 SCL DI I2C clock. Must be connected to GND if no I2C interface E11 AGND GND Analog quiet ground B12, C11, G11, H12 PGND GND Power ground for power voltage converter Table 2: Pin Type Definition Pin Type Description Pin Type Description DI Digital Input AI Analog Input DO Digital Output AO Analog Output DIO Digital Input/Output AIO Analog Input/Output PWR Power Supply GND Ground Datasheet CFR0011-120-00 Revision 3.3 11 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 5 Absolute Maximum Ratings Table 3: Absolute Maximum Ratings Parameter Description TSTG Min Max Unit Storage temperature -65 +165 °C TA Operating temperature -40 +85 °C TJ Junction temperature -40 +125 °C VDD_LIM Limiting supply voltage VBAT, VIN, -0.3 20 V VVOUT_LIM Limiting output voltage converter voltage -0.3 5.5 V VC1P_LIM, VC2P_LIM Limiting flying cap positive pin voltage C1P, C2P -0.3 VO_PVC + 5.5 V VC1N_LIM, VC2N_LIM Limiting flying cap negative pin voltage C1N, C2N -0.3 + 5.5 V VBS1_LIM, VBS2_LIM Limiting bootstrap voltage converter pin voltage BS1, BS2 -0.3 VC1P/C2P + 5.5 V VCORE_LIM Limiting VCORE voltage -0.3 5.5 V VSDA_LIM Limiting voltage at SDA -0.3 5.0 V VSCL_LIM Limiting voltage at SCL -0.3 5.0 V VPIN_LIM Limiting voltage at all pins -0.3 VO_VCORE + 0.3 V RTH Thermal resistance (junction to ambient θJA) 36.8 ºC/W 2 kV VESD_HBM Note 1 6 Electrostatic discharge voltage Conditions (Note 1) PVC_EN =0 and VBAT, VIN ramp < 1 V/µs When the voltage converter is off VC1P = VC2P = VVOUT = 0 Human Body Model (HBM) Stresses beyond those listed under absolute maximum ratings (Table 3) may cause permanent damage to the device. These are stress ratings only, so functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specification are not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Recommended Operating Conditions Table 4: Recommended Operating Conditions Parameter Description Conditions Min Typ Max Unit 5 7.4 10.5 V VDD = VBAT VDD Supply voltage IO_MAX_PVC_DC PVC maximum continuous output current Datasheet CFR0011-120-00 PVC_EN =1 and VBAT, VIN ramp < 1 V/µs 8.2 Revision 3.3 12 of 54 A 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 7 Electrical Characteristics 7.1 Power-On-Reset, Reference Generation and Supervision Table 5: Power-on-Reset, Reference and Supervision Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VIN = 5 V to 10.5 V for standalone/master device Parameter Description IDD_PD Quiescent current in POWER_DOWN mode IDD_ACT Quiescent current in ACTIVE/SLEEP mode (standalone) IDD_ACT_MASTER Conditions Min Typ Max Unit 6 µA PVC enabled in auto. frequency mode no load VDDIO disabled 55 µA Quiescent current in ACTIVE mode (master) PVC enabled in auto. frequency mode no load VDDIO disabled 60 µA IDD_ACT_SLAVE Quiescent current (slave) Master PVC in auto. frequency mode no load VDDIO disabled 10 µA VTH_LO_POR Power on reset lower threshold Measured @VCORE VDD decreasing VTH_HI_POR Power on reset higher threshold Measured @VCORE VDD increasing VTH_UVLO_VDD Under voltage lockout threshold @ VDD VDD decreasing Configurable in 50 mV steps (Note 1) (VBAT_UV_CRIT) VTH_UVLO_ACC Under voltage lockout threshold accuracy VHYST_UVLO_VDD Under voltage lockout hysteresis @ VDD Configurable in 50 mV steps (VBAT_UV_HYS) 50 VTH_WARN Under voltage warning threshold VDD decreasing Configurable in 200 mV steps (VBAT_UV_WARN) VTH_WARN_ACC Under voltage warning threshold accuracy VTH_PG_PVC Power voltage converter power good threshold VTH_PG_ACC Power voltage converter power good threshold accuracy VHYST_PG_PVC Power voltage converter power good hysteresis TTH_WARN (Note 2) Thermal warning threshold temperature 110 125 140 °C TTH_CRIT (Note 2) Thermal critical threshold temperature 125 140 155 °C tACTIVE Time to ACTIVE from 3.5 ms Datasheet CFR0011-120-00 2.8 V 3.7 V 6.15 V +2 % 400 mV 5.2 6.6 V -2 +2 % 5.0 V +2 % 4.6 5.0 -2 Configurable in 100 mV steps (PVC_PG_ADJ) 2.5 200 3.0 -2 100 NONKEY_MODE= 0 Revision 3.3 13 of 54 1.5 mV 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Parameter tEN Description Conditions OFF mode AUTOBOOT = 1 Time to ACTIVE from POWER_DOWN mode NONKEY_MODE= 1 after IC_EN asserted NONKEY_DEBOUNCE = 001 Note 1 PVC requires 5.0 V minimum setting for correct operation. Note 2 Thermal thresholds are non-overlapping. 7.2 Min Typ Max Unit 500 µs Internal Oscillator Table 6: Internal Oscillator Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VDD = 5 V to 10.5 V Parameter Description fOSC Internal oscillator frequency fOSC_ACC Internal oscillator frequency accuracy 7.3 Conditions Min Typ Max 6 After trimming -5 Unit MHz +5 % Power Voltage Converter Table 7: Power Voltage Converter Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VDD = 5 V to 10.5 V and typical external components Parameter Description Conditions Min VDD Supply voltage VDD = VBAT 5.0 VO_PVC Power voltage converter output voltage IOUT = 0 IO_MAX_PVC Power voltage converter maximum output current ILIM_PVC Power voltage converter current limit ILIM_ACC Power voltage converter current limit accuracy Typ Max Unit 10.5 V 50 % 10 11.55 Configurable in 450 mA steps (PVC_ILIM) 4.8 IO = ILIM_PVC trimming range -20 +20 IO = 10 A -10 +10 A A % 80 % ILIM_PVC A 2 * 47 µF 4.7 µF IALARM Current alarm CFLY External flying capacitors Nominal (Note 1) CO_PVC External output capacitor Nominal CLOAD External load capacitor CBS_PVC External boot strap capacitors 1 and 2 Nominal 10 nF CIN_PVC External decoupling capacitor Nominal 2 * 4.7 µF ISTUP_PVC Power voltage converter start-up current Configurable in 500 mA steps (I_STUP_PVC) Datasheet CFR0011-120-00 47 Revision 3.3 14 of 54 500 470 2000 µF mA 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Parameter Description Conditions fSW_PVC Power voltage converter switching frequency Fixed frequency mode 500 kHz ηpeak Power converter peak efficiency VDD = 7.4 V fixed frequency mode / auto. frequency mode 98 % ηPVC Power voltage converter efficiency VDD = 7.4 V IOUT = 30 mA to 3 A, Min Typ Max 97.5 Unit % auto. frequency mode VDD = 7.4 V IOUT = 500 mA to 8 A, Power voltage converter efficiency ηPVC fixed frequency mode 95 % 95 % 13 µA IOUT = 10 mA to 5.5 A auto. frequency mode VDD = 7.4 V IOUT = 1 A to 15 A, Power voltage converter efficiency (master/slave) ηPVCMS fixed frequency mode IOUT = 10 mA to 10 A auto. frequency mode IQ_PVC PVC quiescent current VDD = 7.4 V no load auto. frequency mode Effective capacitance must be CFLY ≥ 18 µF @ 5 V, IRMS = 8 A Note 1 7.4 VCORE Table 8: VCORE Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VDD = 5 V to 10.5 V Parameter Description Conditions Min VDD Supply voltage VDD = VBAT 5.0 VO_VCORE Output voltage @ VCORE IO_VCORE Max load on VCORE VO_VCORE_ACC Accuracy of output voltage at VCORE CO_VCORE External output capacitance @ VCORE (Note 1) Note 1 Typ Max Unit 10.5 V 4.0 -5 Including voltage and temperature coefficient 2.2 V 20 mA +5 % µF Effective external capacitance should be min 0.5 μF, max 1.3 μF and is typically 1.0 μF. Datasheet CFR0011-120-00 Revision 3.3 15 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 7.5 VDDIO Table 9: VDDIO Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VDD = 5 V to 10.5 V Parameter Description Conditions Min Typ Max Unit VDDIO Internal VDDIO voltage rail Internally generated, no external capacitor Configurable via VDDIO_CONF 1.5 1.8 3.3 V VDDIO_ACC Accuracy of internal VDDIO voltage rail +5 % 7.6 -5 Digital I/O Characteristics Table 10: Digital I/O Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC, VDD = 5 V to 10.5 V, VDDIO enabled Parameter Description VIH_ONKEY HIGH level input voltage @ pin nONKEY VIL_ONKEY LOW level input voltage @ pin nONKEY VHYS_ONKEY Conditions Min Typ Max 1.1 V 0.4 Hysteresis voltage @ Unit 100 V mV pin nONKEY VIH_IC_EN VIL_IC_EN RO_PU_GPO IC_EN Input HIGH voltage IC_EN Input LOW voltage 0.7*VCO RE 0.3* VCOR E GPO Pull-down resistor @ GPI RI_PU_ONKEY Pull-up resistor @ nONKEY V NONKEY_MODE = 0x1 Pull-up resistor @ RI_PD_GPI VIH NONKEY_MODE = 0x1 To VCORE GPI_0-1, SCL, SDA, V 24 kΩ 210 kΩ 21 kΩ 0.7*VDDIO V Input HIGH voltage VIL GPI_0-1, SCL, SDA, Input LOW voltage VOH GPO_0-1 Output HIGH voltage Datasheet CFR0011-120-00 0.3* VDDIO Push-pull mode @1 mA Revision 3.3 16 of 54 0.8* (VCORE or VDDIO) V V 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Parameter Description Conditions VOL1 GPO_0-1, SDA, Output LOW voltage VOL3 Max Unit @IOL = 1 mA 0.1 V SDA, Output LOW voltage @IOL = 3 mA 0.24 V VOL20 SDA Output LOW voltage @IOL = 20 mA 0.4 V CGPO_LOAD GPO_0-1 Maximum capacitive load 50 pF CIN_I2C CLK, SDA Input capacitance 10 pF tSP CLK, SDA Spike suppression pulse width 50 10 ns Datasheet CFR0011-120-00 Min Typ 2.5 Fast-mode / Fast-mode Plus High-speed (Hs) mode Revision 3.3 17 of 54 0 0 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 8 I2C Control Bus tF tR tSU_D tBUF 70% SDA 30% tSU_STA tH_D tH_STA tR tW_CH tSP tF tSU_STO 70% SCL 30% 1/fSCL P tW_CL S Figure 6: I2C Bus Timing Table 11: I2C Control Bus Characteristics Unless otherwise noted, the following is valid for TJ = -40 ºC to +125 ºC Parameter Description tBUF Bus free time from STOP to START condition Cb Bus line capacitive load Conditions Min Max 0.5 Unit µs 150 pF 1000 kHz Standard-mode / Fast-mode / Fast-mode Plus fSCL Clock frequency @ pin SCL 0 (Note 1) tSU_STA START condition set-up time 0.26 µs tH_STA START condition hold time 0.26 µs tW_CL Clock LOW duration 0.5 µs tW_CH Clock HIGH duration 0.26 µs tR Rise time @ pin SCL and SDA Input requirement 1000 ns tF Fall time @ pin SCL and SDA Input requirement 300 ns tSU_D Data set-up time 50 ns tH_D Data hold time 0 ns High-Speed Mode fCLK_HS Clock frequency @ pin SCL 0 (Note 1) tSU_STA_HS START condition set-up time 160 ns tH_STA_HS START condition hold time 160 ns tW_CL_HS Clock LOW duration 160 ns tW_CH_HS Clock HIGH duration 60 ns tR_HS Rise time @ pin SCL and SDA Input requirement 160 ns tF_HS Fall time @ pin SCL and SDA Input requirement 160 ns tSU_D_HS Data set-up time 10 ns tH_D_HS Data hold time 0 ns tSU_STO_HS STOP condition set-up time 160 ns Note 1 3400 kHz Maximum clock period is 38 ms if OTP control I2C_TO_EN is enabled. Datasheet CFR0011-120-00 Revision 3.3 18 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 9 Typical Characteristics 9.1 Standalone Operation ηPVC (%) 100 98 96 94 92 90 88 86 84 82 80 1 10 VDD = 5.0V 100 VDD = 7.4V 1000 10000 IO (mA) VDD = 10.5V Figure 7: DA9313 Efficiency Automatic Mode Standalone ηPVC (%) 100 90 80 70 60 50 40 30 20 10 0 1 10 VDD = 5.0V 100 1000 VDD = 7.4V VDD = 10.5V 10000 I (mA) O Figure 8: DA9313 Efficiency Fixed Frequency Mode Standalone Datasheet CFR0011-120-00 Revision 3.3 19 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider VO_PVC (V) 3.70 3.65 3.60 3.55 3.50 3.45 1 10 100 1000 10000 ILOAD (mA) VDD = 7.4V Figure 9: DA9313 Output Voltage Drop Automatic Mode Standalone 9.2 Master/Slave Operation ηPVC (%) 100 98 96 94 92 90 88 86 84 82 80 1 10 VDD = 5.0V 100 VDD = 7.4V 1000 10000 IO (mA) VDD = 10.5V Figure 10: DA9313 Efficiency Automatic Mode Master/Slave Datasheet CFR0011-120-00 Revision 3.3 20 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider ηPVC (%) 100 90 80 70 60 50 40 30 20 10 0 1 10 VDD = 5.0V 100 1000 VDD = 7.4V VDD = 10.5V 10000 IO (mA) Figure 11: DA9313 Efficiency Fixed Frequency Mode Master/Slave VO_PVC (V) 3.70 3.65 3.60 3.55 3.50 3.45 1 10 100 1000 10000 IO (mA) VDD = 7.4V Figure 12: DA9313 Output Voltage Drop Automatic Mode Master/Slave Datasheet CFR0011-120-00 Revision 3.3 21 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10 Functional Description DA9313 is a 2S compliant high-voltage power converter that generates an unregulated 1S output voltage (VOUT) of half of VIN using a capacitive interleaved charge-pump divider. VOUT is a 10 A peak current output in standalone configuration and 20 A peak current when driven from two DA9313 chips paired in master/slave configuration. Host communication is not required for operation with OTP loading to configure DA9313 on start-up. However, an I2C interface is available for host configuration of the register map if required. In addition, the GPIOs can be configured as nIRQ for fault signaling and recovery. An internal LDO can be enabled to supply VDDIO if required. 10.1 Start Up DA9313 is OTP configured as a standalone or master/slave variant. The OTP variants are described in a separate document. 10.1.1 Standalone Operation DA9313 starts as a standalone device as default, when master/slave operation is not enabled (MSTSLV_IF_EN bit is set to 0). On battery insertion the full OTP content is loaded to the register map. DA9313 self-checks that the system is stable and then proceeds to ACTIVE Mode or POWER_DOWN Mode as configured by the AUTOBOOT bit. POWER_DOWN mode is an ultra-low power state of the system implemented to extend the shelf life of applications with a battery connected during shipping and before first user boot. DA9313 can be brought from POWER_DOWN mode to ACTIVE mode via a user press of the nONKEY pin (the user, or external IC, activated power on/off button). Once in ACTIVE mode the system will perform as configured in either automatic or fixed frequency mode, see section 10.3.3. To ensure minimal quiescent current requirements the oscillator is enabled only on demand, see section 11.8. If necessary, the system can safely transfer clocking from the internal oscillator to an external clock (within the specified operating frequency, see Table 6) via GPIO configuration, see section 10.2.1.4. DA9313 responds to critical faults by power cycling the device to protect circuitry, see section 11.5. 10.1.2 Master/Slave Operation DA9313 starts in master/slave mode when MSTSLV_IF_EN bit is set to 1. GPIO_0 operates as the master/slave interface (MS_IF) and is pulled down internally. On the master device, GPIO_1 should not be driven externally. To configure the device as slave, GPIO_1 should be tied to VCORE of the slave device, see Figure 2. DA9313 will remain in this state unless a cold boot is performed by removing the battery. The master takes control over the slave in such a way that the slave always operates in POWER_DOWN Mode. Datasheet CFR0011-120-00 Revision 3.3 22 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.1.2.1 Master Operation In master operation, GPIO_0 operates as the master slave interface (MS_IF) and provides the PVC phase and enable/disable sequencing controls from the master to the slave. The start-up time is extended to ensure that the slave device completes the cold boot to POWER_DOWN mode sequence. Once the slave device has entered POWER_DOWN Mode, the master device enters ACTIVE Mode and GPIO_0 is configured as a push-pull GPO for use as a master/slave interface (MS_IF). After the master device has entered ACTIVE mode, the master PVC triggers the slave PVC over the MS_IF. GPIO_1 is functional in the master and can be configured via I2C. NOTE All master IOs, GPIO_1 and I2C, are supplied from VCORE in master mode not VDDIO. Thus I2C communications are only possible if host I2C IOs also run from a 4 V supply, or are externally level shifted. 10.1.2.2 Slave Operation When the device is operating as slave, it goes directly to POWER_DOWN Mode. There is no communication to the slave (slave I2C lines are grounded) and the master controls the slave PVC directly via MS_IF. 10.2 Interface Functions DA9313 incorporates two general purpose input/output pins (GPIOs) and a dual mode onkey (nONKEY) pin. Functions are assigned to the GPIOs via GPIO_CTRL and GPIO_CTRL_2 registers and to nONKEY via NONKEY_MODE in the MODE_CTRL register. Table 12: GPIO Configuration Overview GPIO Input Functionality Output Functionality Alternative Functionality GPIO_1 GPI (Note 1) PVC_EN GPO (Note 1) PG Digital clock input (Ext_Clk_Inp) SLAVE_ID SLEEP_EN PWC nIRQ (Note 1) GPI (Note 1) PVC_EN GPO (Note 1) PG SLEEP_EN PWC nIRQ (Note 1) GPIO_0 Note 1 10.2.1 Master/slave control interface (MS_IF) Valid when I2C is enabled GPIOs A power good (PG) indicator can be routed to either GPIO for host power up sequencing. The power voltage converter enable, disable, and status field, PVC_EN, can be controlled via I2C or GPI. The system controller can also be moved to a configurable SLEEP mode via I2C or GPI control. NOTE When DA9313 is in master/slave mode all GPI’s must be referenced to VCORE. 10.2.1.1 PVC Enable The PVC can be disabled by an external PMIC (supplied from a different rail to the DA9313 PVC output). This function is only provided in ACTIVE Mode and SLEEP Mode when VDDIO_EN bit is high. Either GPIO_1 or GPIO_0 can be configured as a PVC_EN pin via the GPIO_CTRL register, GPIO_1_PIN and GPIO_0_PIN. The PVC_EN pin controls the PVC_EN bit in the PVC_CTRL Datasheet CFR0011-120-00 Revision 3.3 23 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider register, allowing read-back of the current setting. The PVC_EN bit can also be controlled over I2C when not set to be driven from GPIO_1 or GPIO_0. 10.2.1.2 SLEEP Enable In order to reduce power consumption to a minimum, the host processor can send DA9313 into SLEEP Mode. SLEEP mode is a configurable mode with configuration via the SLEEP_CTRL register. This function is available in ACTIVE Mode and SLEEP mode when VDDIO_EN bit is high. Any GPI pin can be configured as SLEEP_EN via the GPIO_1_PIN and GPIO_0_PIN bits. The SLEEP_EN pin controls the SLEEP status bit in the MODE_CTRL register allowing read-back of the current setting. The SLEEP bit can also be controlled over I2C when not set to be driven from GPI, see section 11.4. 10.2.1.3 Power Cycle The power cycle (PWC) input allows the host to perform a power cycle of DA9313 with OTP reload. This function is provided in ACTIVE Mode and SLEEP Mode when VDDIO_EN bit is high. Any GPI pin can be configured as PWC via the GPIO_1_PIN and GPIO_0_PIN bits. After PWC assertion DA9313 de-asserts the power good (PG) pin for 10 µs and then initiates a power cycle. The GPI_RESET bit is set in the FAULT_LOG for host read-back following power cycle back to ACTIVE mode. 10.2.1.4 Clock Input GPIO_1 supports the connection of an external oscillator delivering the target 6 MHz, see Table 6, to the system. This requires that GPIO_1 is selected for external clock input (Ext_Clk_Inp) via GPIO_1_PIN. The GPI does not generate any event in this case. The switch over from the internal to external clock occurs on the falling edge of the clock. If the external clock is not present, a clock detect switches control to the internal clock. In this case, I 2C communication is possible. CAUTION Removing an external clock without first reverting the internal clocking GPI setting may damage the device. 10.2.1.5 Output Ports Output ports (GPOs) are supplied from the internal rail (VCORE or VDDIO) and can be configured to be open drain or push-pull (selected via GPIO_1_MODE or GPIO_0_MODE). If a GPO is used as a push-pull driver VDDIO has to be enabled. GPOs can also be supplied from an external rail by disabling the internal 20 kΩ pull-up resistor in open-drain mode. If the output ports are defined as general purpose outputs (GPOs), the low/high level is defined in register bits GPIO_1_TYPE or GPIO_0_TYPE. If the output ports are associated to power good (PG), defined by GPIO_1_PIN and GPIO_0_PIN, the GPIO_1_TYPE or GPIO_0_TYPE fields indicates the active low/high characteristics. NOTE In master/slave mode, with GPIO_1 operating in open drain with an external pull-up, the pull-up resistor must be > 820 kΩ to prevent a false SLAVE_ID recognition. Datasheet CFR0011-120-00 Revision 3.3 24 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.2.1.6 Power Good Indication Power good (PG) voltage monitoring at the PVC output can be enabled. The PG function monitors the VOUT rail and informs the host processor about a power cycle in advance of the power cycle occurring. PG indication is selected via GPIO_1_PIN or GPIO_0_PIN . The voltage monitoring threshold can be configured between 2.5 V and 5 V in 100 mV steps via PVC_PG_ADJ. When the voltage drops below the VTH_PG_PVC threshold, the event E_PVC_PG is generated and the PG pin is de-asserted. Active level is configurable via GPIO_0_TYPE. After an under voltage condition has been triggered, the indicator will return back to PG after the output voltage has recovered above VTH_PG_PVC + VHYS_PG_PVC, see Table 5. When a power cycle is initiated the PG will be always be de-asserted for 10 µs in advance of the power cycle occurring before exiting ACTIVE or SLEEP mode. 10.2.1.7 nIRQ GPIO_0 and GPIO_1 both support an nIRQ function that indicates that an interrupt causing event has occurred. The related event and status information, such as warnings about temperature and voltages, over-current fault conditions or status changes at GPI ports, is available in the EVENT and STATUS registers. The nIRQ output is enabled via GPIO_1_PIN or GPIO_0_PIN. nIRQ can be push-pull or open drain, selected via GPIO_1_TYPE or GPIO_0_TYPE, and can be active LOW or active HIGH. The EVENT registers hold information about the events that have occurred. Events are triggered by a status change at the monitored signals. When an event bit is set the nIRQ signal is asserted, unless this interrupt is masked by the appropriate in MASK register. The masked bits only mask the nIRQ assertion, and do not suppress the event generation. The nIRQ is not released until all event bits are cleared by writing a 1 to the appropriate EVENT register bits. New events which have occurred during the reading of the EVENT register are held until the register has been cleared; ensuring that host processor does not miss them. 10.2.2 nONKEY The nONKEY pin can be configured via the NONKEY_MODE register. It can operate as a user power button or as a level sensitive IC_EN pin, which allows the DA9313 state to be controlled from the GPO of another device. The nONKEY input port is always enabled to ensure that activities which should generate an application wake-up or power down are always captured. The level of the debounced signal is provided by the status flag nONKEY. NOTE The nONKEY port should be never externally overdriven to a voltage higher than VCORE. 10.2.2.1 Event Generation In ACTIVE or SLEEP modes a press of nONKEY causes an IRQ assertion if not suppressed via the interrupt mask M_nONKEY. The event can be generated from either the rising or the falling edge of the nONKEY pin via NONKEY_PIN setting: 0: An E_nONKEY event is generated when the debounced signal from port nONKEY goes low (asserting edge). If not masked, an interrupt is signaled to the host via nIRQ. 1: An E_nONKEY event is generated when the debounced signal from port nONKEY goes high (de asserting edge). If not masked, an interrupt is signaled to the host via nIRQ. Datasheet CFR0011-120-00 Revision 3.3 25 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.2.2.2 Press Detection Host notification of button presses via a maskable interrupt is available from the STATUS register, field nONKEY. A configurable long press can be used to trigger a power cycle of the device as a blue-screen lock up escape. 10.2.2.3 Wake Up When DA9313 is in POWER_DOWN mode a user press of the nONKEY, for longer than the configured debounce setting in NONKEY_DEBOUNCE, triggers a transition to ACTIVE mode. NOTE Subsequent de-asserting edges of the nONKEY following a wake-up from POWER_DOWN require a release of the external button and new assertion to generate subsequent events. 10.2.2.4 Long Press When DA9313 is in ACTIVE mode, a user press of the nONKEY, for longer than the configured debounce setting in NONKEY_DEBOUNCE plus the KEY_DELAY and SHUT_DELAY settings, triggers a power cycle which results in the device entering ACTIVE or POWER_DOWN mode (depending on the settings in NONKEY_CYCLE). If a long press of nONKEY has been detected, DA9313 will power cycle in 1 s unless this bit is cleared by the host, see E_KEY_RESET. 10.2.2.5 External IC Enable The operation of the pin as an external IC enable (IC_EN) is configured in OTP via NONKEY_MODE. In this mode, the pin must be driven externally to VCORE or pulled to ground. The level of the nONKEY port controls transitions between ACTIVE (IC_EN high) and POWER_DOWN (IC_EN low). During cold boot it is the responsibility of the host processor and the external application to make sure that the level of IC_EN is correct. There should be external resistors, in the 100 kΩ range, defining the correct level when the port is not actively driven. The FAULT_TIME system controller state is bypassed when moving from ACTIVE to POWER_DOWN due to IC_EN de assertion but is still enabled for fault handling. NOTE When NONKEY is set as IC_EN, SLEEP mode has a restricted usage. System behavior is only guaranteed if SLEEP mode is entered / exited via I2C/GPI while IC_EN is high, using SL_nONKEY_CONT as SLEEP mode exit is invalid as this will bring chip to POWER_DOWN on the de-asserting edge of IC_EN Datasheet CFR0011-120-00 Revision 3.3 26 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.3 Power Voltage Converter The high efficiency 2S to 1S power voltage converter (PVC) is capable of supplying multiple 1S voltage rails with up to 10 A output current. The dual phase interleaved operation ensures an almost constant input current, thereby highly improving the application design against noise. 10.3.1 PVC Output Voltage The PVC can be configured via OTP or I2C and outputs a non-regulated voltage which is nominally half of the input voltage, in the case where no load is applied. When a current (I OUT) is drawn at the VOUT node and the PVC is switching at frequency of fSW_PVC, the output voltage is determined as: VOUT = VIN − REQ  I OUT 2 Where: ● REQ is a function of the sum of all resistances in the input/output power path (including the power device’s on-resistance and the PCB routing resistance) as well as the switching frequency, C FLY and PCB parasitics. The voltage ripple at VOUT can be first order approximated as the voltage drop due to the discharge of the CFLY capacitor in half of the period at an fSW_PVC switching frequency, plus the discharge voltage of the output VOUT capacitor during a typical 30 ns short dead time for phase switch. In addition, the PVC provides an optional hardware enable/disable via selectable GPI, configured via the PVC_EN register field, see section 10.2.1.1. 10.3.2 PVC Start-Up The PVC can be OTP configured to enable on entry to ACTIVE mode and to run in automatic (mixed DCM and CCM based on load sensing) or in fixed frequency (CCM). Alternatively the PVC can be set to CCM in ACTIVE mode and to run in automatic in SLEEP mode. See section 10.3.3. During PVC start-up, the PVC does not switch and the flying capacitors CFLY are connected in parallel to the output capacitor CLOAD. An internal current source charges the capacitors up to a voltage value close to the target average in normal operation. The internal current source can be configured from 500 mA to 2000 mA via I_STUP_PVC. At the end of the start-up phase the normal switching operation of the PVC is restored. NOTE A start-up phase with an output load greater than I_STUP_PVC will not be successful. The PVC has a ramp-up timer which checks the ramp-up happens in approx. 20 ms. If the output voltage has not reached a value close to VDD/2 at this time this indicates a failure condition and the regular switching is not started. This is reported as PVC_RAMPUP in FAULT_LOG. CAUTION To avoid damage to the device, the PVC output must reach VDD/2 – 80 mV before a load greater than half of I_STUP_PVC can be applied to its output. Datasheet CFR0011-120-00 Revision 3.3 27 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.3.3 PVC Operating Modes 10.3.3.1 Standalone Mode When the PVC is enabled, the operating mode is defined by the PVC_MODE register field. The PVC operates either in fixed frequency (PVC_MODE= 0) or in automatic frequency mode (PVC_MODE= 1). In automatic frequency mode, the switching frequency is not always constant, see Figure 13. The PVC operates in continuous conduction mode (CCM) at high loads and moves to discontinuous conduction mode (DCM) as soon as the load becomes lower than a certain threshold. ● When the load decreases, the VOUT voltage increases over the VPVC_DROP threshold and the PVC moves from CCM to DCM. ● When the load increases again and the VOUT voltage decreases by VPVC_HYST below VPVC_DROP and the PVC moves back from DCM to CCM. Operating in automatic frequency mode extends the efficiency range to low levels of output loads, enabling the PVC to supply a low voltage PMIC in low power mode over a long period. VBAT/2 Load Decreasing Sudden Load Applied Light Load Load Decreasing Vpvc_drop DCM threshold VOUT DCM request skip Sudden Load skip Vpcv_hyst Vpvc_ms_drop skip Unloading CCM Request Vpvc_ms_hyst MSI Master :CCM Slave : OFF Master :DCM Slave : OFF Master: CCM Slave: OFF Master : CCM Slave : ON Master: CCM Slave: OFF Master: DCM Slave : OFF Figure 13: Master Slave Timing in Automatic Frequency Mode 10.3.3.2 Master/Slave Operation The master device behaves in the same way as a standalone device, see section 10.3.3.1, with additional VOUT monitoring at VMSI level (see Note below). This monitoring is used to trigger the slave device via the master/slave interface (MS_IF). The level at which the master triggers the slave is defined in PVC_MS_DROP. When the VOUT voltage decreases beyond VMSI due to progressive output loading, the master DA9313 enables the slave DA9313 over MS_IF. When the VOUT voltage increases above VMSI + VPVC_MS_HYST (defined in PVC_MS_HYST), the master DA9313 disables the slave DA9313 over MS_IF. Disabling the master PVC triggers a shutdown of the slave PVC over MS_IF. NOTE VMSI = VCCM – VPVC_MS_DROP Where: ● ● VCCM = (VBAT/2 - VPVC_DROP - VPVC_HYSTMAX) VPVC_HYSTMAX is a constant value of 30 mV Datasheet CFR0011-120-00 Revision 3.3 28 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 10.3.4 PVC Power Down During PVC power down, the PVC does not switch and the flying capacitors C FLY are connected in parallel to the output capacitor CLOAD. An internal pull-down is used to ensure the PVC is in a defined start condition. When the output voltage drops below the threshold of 1 V, the PVC can accept a restart. In master/slave configuration, power down is synchronized by the master/slave interface (MS_IF) in a way where both devices connect the flying capacitors (CFLY) in parallel to the output capacitor (CLOAD) at the same time. These capacitors are discharged by the master. 10.3.5 PVC Current Limit The configurable integrated current limit is aimed to protect DA9313’s power stages and the external components from excessive current. When hitting the current limit ILIM_PVC (configured in PVC_ILIM) DA9313 enters FAULT RECOVERY. DA9313 provides an indication that the system current is approaching the critical limit, before hitting the current limit itself, allowing an active host processor to take some countermeasures. When the warning threshold IALARM is reached the event E_PVC_OC_WARN is generated. The status of the over-current alarm comparator can be read back on FAULT_LOG via the I2C control interface. Datasheet CFR0011-120-00 Revision 3.3 29 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 11 Operating Modes OFF mode VCORE ≥ VTH_HI_POR Fault no longer present Power cycle to POWER_DOWN from ACTIVE or SLEEP mode? FAULT RECOVERY mode Yes No REGMAP_RESET Safety pause complete OTP_LOAD Cold boot & AUTOBOOT = 0? FAULT_TIME Yes POWER_DOWN mode No Power cycle from: critical fault SOFT_RESET or LONGPRESS ACTIVE mode SLEEP_EN !IC_EN !SLEEP_EN SLEEP mode IC_EN or NONKEY WAKE press Figure 14: Operating Modes Datasheet CFR0011-120-00 Revision 3.3 30 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 11.1 OFF Mode (HARDRESET) DA9313 is in OFF mode without being supplied or with a low supply, when V O_VCORE ≤ VTH_LO_POR. The only circuitry enabled is the VCORE regulator and its voltage supervision. The digital core is kept reset in OFF mode. When VO_VCORE ≥ VTH_HI_POR DA9313 transitions from OFF mode to ACTIVE mode or to POWER_DOWN mode, depending on the AUTOBOOT setting. 11.2 POWER_DOWN Mode The POWER_DOWN mode is the lowest quiescent current operating mode with a valid input voltage. It can support a shelf mode for applications with integrated battery packs, which allows connecting pre-charged batteries before the user enables the device for the first time. PVC, oscillator, and analog references are disabled, only the nONKEY sense circuit is left running on VCORE. A nONKEY wake press will transition the system to ACTIVE, see section 10.2.2.3. 11.3 ACTIVE Mode ACTIVE mode is the main operating mode of DA9313 and is entered into after OTP load. The PVC is then automatically turned on and operates in the configured mode. NOTE The host processor should wait for DA9313 to reach the ACTIVE mode following a start-up from OFF or POWER_DOWN before starting the I2C communication with DA9313, see Table 5 for timing details. After the application starts up, the host processor should always read the FAULT_LOG register to determine which one of the following sequences occurred before ACTIVE mode was enabled: ● ● ● ● ● from a fault condition (dedicated fault bit) from OFF during cold boot (POR bit) from power cycle due to long press of nONKEY from power cycle initiated via SOFTRESET write from power cycle initiated by PWC 11.4 SLEEP Mode SLEEP mode is used to support application low power modes with lower quiescent current. The mode can be entered into and exited from by register write or via GPI. An optional exit via nONKEY is also supported when VDDIO has been disabled in SLEEP mode. SLEEP mode is configurable via the SLEEP_CTRL register, see Table 13 for configuration options. ● To enter SLEEP mode via I2C, assert the SLEEP bit in the MODE_CTRL register. ● To enter SLEEP mode via GPI, configure GPIO_1_PIN or GPIO_0_PIN to SLEEP_EN. The level of the GPI controls entry into SLEEP mode and exit back to ACTIVE mode. ACTIVE configuration settings are re-applied on exit of SLEEP mode. Table 13: SLEEP_CTRL Register Configuration Control bit Block PVC_SL PVC operation in SLEEP mode: 0: no change 1: automatic frequency mode The PVC is changed to automatic frequency mode (variable frequency). PVC_MODE setting is overwritten (old value restored at the exit of SLEEP mode) Datasheet CFR0011-120-00 Revision 3.3 31 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Control bit Block PVC_DIS_SL PVC enable control, in SLEEP mode: 0: no change 1: PVC disabled The PVC is disabled PVC_EN setting is overwritten (old value restored at the exit of SLEEP mode) VDDIO_DIS_SL Control VDDIO supply enable, in SLEEP mode: 0: no change 1: VDDIO rail disabled. 11.5 FAULT RECOVERY Mode DA9313 responds to critical under-voltage, over-current, and over-temperature conditions and safely power cycles the device through FAULT RECOVERY mode. Fault events are captured in the FAULT_LOG register for host interrogation on reboot and warning levels generate maskable interrupt events. FAULT RECOVERY is a temporary mode and is automatically entered and exited depending on fault condition presence. DA9313 enters FAULT RECOVERY mode from ACTIVE or SLEEP mode. In POWER_DOWN mode there is no supervision therefore FAULT RECOVERY mode cannot be entered. The device waits for a configurable FAULT_TIME, when the PVC is disabled, to ensure discharge of all critical nodes in the application before any attempt to reboot. DA9313 automatically exits FAULT RECOVERY mode when the fault condition has expired. The FAULT_LOG register can be reset by a register write of 1 to the appropriate register bit. 11.5.1 Input Under-Voltage VBAT voltage is continuously sensed, except in RESET and POWER_DOWN modes, by dedicated analog circuitry based on two configurable levels: a warning level, VTH_WARN and a shutdown level, VTH_UVLO_VDD. The upper comparator triggers a warning if VBAT drops below VTH_WARN. The lower comparator triggers a fault condition if VBAT drops below VTH_UVLO_VDD. The VTH_UVLO_VDD voltage threshold is configurable and can be set via VBAT_UV_CRIT_THRSH from 4.6 V to 6.15 V (5.0 V default) in steps of 50 mV. The VHYST_UVLO_VDD hysteresis can be also be configured via VBAT_UV_HYS from 50 mV to 400 mV (200 mV default) in steps of 50 mV. The VTH_WARN voltage threshold is configurable and can be set via VBAT_UV_WARN from 5.2 V to 6.6 V in steps of 200 mV. To reduce the current consumption of the block only the warning comparator is permanently on, the shutdown comparator is enabled on demand in the interval where VBAT is below the warning threshold. The critical under voltage threshold comparator is also debounced, this guarantees that short spikes do not trigger the application power-down. When the warning comparator triggers, the status bit VBAT_WARN is asserted and the event E_VBAT_WARN is generated. If not masked via M_VBAT_WARN, the output port nIRQ is asserted (providing a GPIO is configured as nIRQ). The host processor is then informed that the input voltage level is close to critical and it can take action such as powering down the application. If the input voltage keeps dropping and the shutdown comparator is triggered the PVC is disabled and the VBAT_UV_CRIT bit is asserted in FAULT_LOG. When the VBAT voltage recovers over VTH_UVLO_VDD + VHYST_UVLO_VDD, DA9313 enters ACTIVE mode after having performed an OTP read. Datasheet CFR0011-120-00 Revision 3.3 32 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 11.5.2 Over-Temperature FAULT RECOVERY mode is entered when TJ ≥ TTH_CRIT and is exited when TJ < TTH_CRIT. The TEMP_CRIT bit is asserted in FAULT_LOG. 11.5.3 PVC Current Limit When the PVC hits the current limit, FAULT RECOVERY mode is entered and is immediately exited, because the root cause (current limit reached) is removed when the PVC is disabled. The PVC_OC_CRIT bit is asserted in FAULT_LOG. 11.5.4 PVC Start-Up Failure FAULT RECOVERY mode is entered when the PVC has failed its start-up procedure. This occurs when the output voltage has not reached a voltage close to VDD/2 within approximately 20 ms. FAULT RECOVERY mode is immediately exited and a new power up is started. The PVC_RAMPUP bit is asserted in FAULT_LOG. 11.6 VCORE Voltage Regulator The VCORE supply is a 4 V rail internally generated by DA9313 for the internal analog and digital supply. It is always enabled except in OFF mode. The additional VDDIO rail is internally generated directly from VCORE. The slave has VDDIO disabled. VCORE is the only regulator with an external bypass capacitor and can supply up to 20 mA to an external circuit. 11.7 VDDIO Generation The VDDIO rail is internally generated by DA9313 from VCORE and is assigned to the I/O interfaces and to the GPIOs. The VDDIO is controlled via VDDIO_EN bit. The rail assignment determines the IO voltage levels and logical thresholds see section 7.5. A specific VDDIO voltage can be selected via VDDIO_CONF (1.5 V, 1.8 V, 2.8 V, or 3.3 V). The VDDIO generation is off in OFF and POWER_DOWN modes, and always in the slave device. In SLEEP mode the VDDIO generation is disabled if VDDIO_SL is asserted. The internally generated VDDIO is monitored for under voltage VTH_UVLO_IO. If VDDIO voltage is not in range, the I2C interface is reset. All IOs are run from VCORE if VDDIO is disabled. All IOs are supplied on VCORE only when in master/slave mode (it is not possible to enable VDDIO in these modes). Datasheet CFR0011-120-00 Revision 3.3 33 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 11.8 Internal Oscillator The internal high-speed oscillator generates a signal at fOSC, the internal 6 MHz clock reference. The high-speed oscillator is enabled on demand. It is possible to apply an external oscillator delivering the target 6 MHz, see Table 6, to the system. This requires that GPIO_1 is selected as Ext_Clk_Inp on GPIO_1_PIN. GPIO_1 does not generate any event in this case. 11.8.1 Internal Temperature Supervision Due to the high power density and to protect DA9313 from damage due to excessive power dissipation the internal temperature is continuously monitored, except in DCM, OFF and POWER_DOWN modes. There are two temperature thresholds, TTH_WARN and TTH_CRIT, respectively at typically 125 °C and 140 °C. To minimize the current consumption only the T TH_WARN comparator is always on. The TTH_CRIT comparators are enabled on demand at >125 °C when TTH_WARN is reached. When the junction temperature reaches the TTH_WARN threshold, DA9313 will assert the bit TEMP_WARN and will generate the event E_TEMP_WARN. The status bit TEMP_WARN will remain asserted as long as the junction temperature is higher than TTH_WARN. When the junction temperature increases further over T TH_CRIT DA9313 will immediately disable the PVC, will assert the status bit TEMP_CRIT and will progress to FAULT RECOVERY mode, see section 11.5. The status bit TEMP_CRIT will remain asserted as long as the junction temperature is higher than TTH_CRIT. DA9313 will remain in FAULT RECOVERY mode as long as the junction temperature is bigger than TTH_CRIT and will not allow re-enabling of the supplies via I2C port or register write. Where the I2C interface is not connected, providing DA9313 has been configured to boot to ACTIVE mode via AUTOBOOT, the PVC will shut down (power cycle) then restart and PG on GPIO will go down and then up again. Datasheet CFR0011-120-00 Revision 3.3 34 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 12 Control Interface I2C is always enabled in ACTIVE/SLEEP and IOs run on either VDDIO or VCORE, see section 11.7. DA9313 can be software controlled through an I2C serial control interface. Data are shifted into or out of DA9313 under the control of the host processor that also provides the serial clock. In a normal application case the interface is only configured once from OTP values, which are loaded during the initial start-up of DA9313. In this phase the I2C address is loaded from OTP. The LOCK_REG register provides a software-controlled write protection (soft lock) of selected registers from 0xE0 to 0x2F, the registers remain readable. This feature prevents malicious or accidental writes to these critical registers from damaging the device. This soft lock is intended for control by the system driver during device configuration on power up. NOTE The soft lock will reassert during all power cycles. 12.1 I2C Communication DA9313 has an OTP configurable device write address (default: 0xD0) and an OTP configurable device read address (default: 0xD1). The 4 MSB of the I2C device address can be OTP configured in the register field IF_BASE_ADDR1. The SCL port functions as the I2C clock and the SDA port carries the bi-directional I2C data. NOTE SDA and SCL must be connected to GND if I2C is not being used. The slave SDA and SCL must always be connected to GND. The I2C interface is open-drain supporting multiple devices on a single line. The bus lines have to be pulled high by external pull-up resistors (2 kΩ to 20 kΩ range). The devices connected to the I 2C SDA can only drive the bus line low to ground. As a result two devices cannot conflict if they drive the bus simultaneously. In Standard/Fast mode the highest frequency of the bus is 400 kHz. The exact frequency can be determined by the application and does not have any relation to the DA9313 internal clock signals. DA9313 does not initiate any clock arbitration or slow down the clock. An automatic I2C reset can be triggered via control I2C_TO_EN if the clock signal stays low for more than 35 ms. The interface supports an operation compatible to Standard, Fast, Fast-Plus and High Speed mode of the I2C-bus specification Rev 4 [1]. The operation in High Speed mode at 3.4 MHz requires mode changing in order to switch spike suppression and slope control characteristics compatible to the I 2Cbus specification. The High Speed mode can be enabled on a transfer by transfer basis by sending the master code (0000 1XXX) at the begin of the transfer.DA9313 does not make use of clock stretching and delivers read data, without additional delay, up to 3.4 MHz. Alternatively the interface can be configured to continuously use High Speed mode via PM_IF_HSM (OTP configurable), so that the master code is not required at the beginning of every transfer. This reduces the communication overhead on the bus but limits the attachable slaves to the bus to compatible devices. The communication on the I2C bus always takes place between two devices, one acting as the master and the other as the slave. The DA9313 will only operate as a slave. The master or standalone device has stored the device address in register IF_BASE_ADDR1. NOTE When DA9313 is operating in master/slave mode, the I2C bus is referenced to 4 V. 12.2 I2C Control Bus Protocol Data are transmitted over the I2C bus in groups of 8 bits. To send a bit the SDA line is driven to the intended state while the SCL is low (for example, a low on SDA indicates a zero bit). Once the SDA Datasheet CFR0011-120-00 Revision 3.3 35 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider has settled the SCL line is brought high and then low. This pulse on SCL clocks the SDA bit into the receivers shift register. DA9313 uses a two byte serial protocol which contains one byte for the address and one byte for data. Data and address transfer is based on the MSB transmitted first for both read and write operations. All transmission begins with the START condition from the master as long as the bus is in IDLE state (the bus is free). The START condition is defined as a high to low transition at the SDA line while the SCL is high. The STOP condition is defined as a low to high transition at the SDA line while the SCL is high. SCL SDA Figure 15: Timing of I2C START and STOP Condition The I2C bus will be monitored by DA9313 for a valid SLAVE address whenever the interface is enabled. It responds immediately when it receives its own slave address. This acknowledge is done by pulling the SDA line low during the following clock cycle (white blocks marked with A in Figure 16 to Figure 20). The protocol for a register write from master to slave consists of a START condition, a slave address with read/write bit and the 8-bit register address followed by 8 bits of data terminated by a STOP condition (all bytes responded to by DA9313 with Acknowledge): S SLAVEadr 7-bits W A REGadr 1-bit A DATA 8-bits Master to Slave A P 8-bits Slave to Master S = START condition P = STOP condition A = Acknowledge (low) W = Write (low) Figure 16: I2C Byte Write (SDA Line) When the host reads data from a register it first has to write access DA9313 with the target register address and then read access DA9313 with a Repeated START or alternatively a second START condition. After receiving the data the host sends No Acknowledge and terminates the transmission with a STOP condition: S SLAVEadr W A 7-bits S 1-bit 1-bit Master to Slave A Sr SLAVEadr 8-bits SLAVEadr W A 7-bits REGadr 7-bits REGadr A P S R A 7-bits * A P 8-bits SLAVEadr 8-bits DATA 1-bit R A 1-bit DATA * A P 8-bits Slave to Master S = START condition Sr = Repeated START condition P = STOP condition A = Acknowledge (low) * A = No Acknowledge W = Write (low) R = Read (high) 2 Figure 17: I C Byte Read (SDA Line) Consecutive (page) read out mode is initiated from the master by sending an Acknowledge instead of No Acknowledge after receipt of the data word. The I2C control block then increments the address pointer to the next I2C address and sends the data to the master. This enables an unlimited read of data bytes until the master sends a No Acknowledge directly after the receipt of data, followed by a subsequent STOP condition. If a non-existent I2C address is read out then the DA9313 will return code zero: Datasheet CFR0011-120-00 Revision 3.3 36 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider S SLAVEadr W A 7-bits 1 bit S SLAVEadr W A 7-bits 1-bit REGadr A Sr SLAVEadr R A 8-bits 7-bits REGadr DATA 1-bit DATA 8-bits 7-bits 1-bit A 8-bits S SLAVEadr R A A P 8-bits Master to Slave A DATA * DATA A P 8-bits A DATA 8-bits * A P 8-bits Slave to Master S = START condition Sr = Repeat START condition P = STOP condition A = Acknowledge (low) * A = No Acknowledge W = Write (low) R = Read (high) 2 Figure 18: I C Page Read (SDA Line) NOTE The slave address after the Repeated START condition must be the same as the previous slave address. Consecutive (page) write mode is supported if the master sends several data bytes following a slave register address. The I2C control block then increments the address pointer to the next I 2C address, stores the received data and sends an Acknowledge until the master sends the STOP condition. S SLAVEadr W A 7-bits 1 bit REGadr A 8-bits DATA 8-bits Master to Slave A DATA 1-bit A 8-bits DATA A 8-bits ………. A P Repeated writes Slave to Master S = START condition Sr = Repeat START condition P = STOP condition A = Acknowledge (low) * A = No Acknowledge W = Write (low) R = Read (high) Figure 19: I2C Page Write (SDA Line) An alternative write mode, alternating register address and data, can be configured via register bit WRITE_MODE. Register addresses and data are sent alternately, see Figure 20, to support host repeated write operations that access several non-consecutive registers. Data will be stored at the previously received register address. An update of WRITE_MODE cannot be done without interruption within a transmission frame. Thus, if not previously selected or not set as OTP default, the activation of Repeated Write must be done with a regular write on WRITE_MODE followed by a STOP condition. The next frame after a START condition can be written in Repeated Write S SLAVEadr W A 7-bits 1 bit REGadr 8-bits Master to Slave A DATA 8-bits A REGadr 1-bit 8-bits A DATA 8-bits A ………. A P Repeated writes Slave to Master S = START condition Sr = Repeat START condition P = STOP condition A = Acknowledge (low) * A = No Acknowledge W = Write (low) R = Read (high) Figure 20: I2C Repeated Write (SDA Line) If a new START or STOP condition occurs within a message, the bus will return to IDLE-mode. Datasheet CFR0011-120-00 Revision 3.3 37 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 13 Register Definitions Table 14: Register Map Addres Name 7 6 5 4 RESET_CYCL nONKEY_CYC E LE 3 2 1 0 SOFTRESET SLEEP s# Register Page 0 0x01 VENDORID VENDORID 0x02 MODE_CTRL Reserved 0x03 SLEEP_CTRL Reserved 0x04 PVC_CTRL Reserved 0x05 GPIO_CTRL Reserved GPIO_1_PIN 0x06 GPIO_CTRL_2 GPIO_1_PD GPIO_1_PU INTERFACE_CT WRITE_MOD RL E 0x08 NONKEY_CTRL SHUT_DELAY 0x09 MASK Reserved 0x0A STATUS 0x0B EVENT 0x0C FAULT_LOG 0x0D LOCK_REG LOCK_REG 0x0E PVC_CONFIG_1 PVC_DROP PVC_HYST PVC_MS_DROP 0x0F PVC_CONFIG_2 PVC_SLV_IF_PHASE Reserved PVC_ILIM 0x10 PVC_CONFIG_3 PVC_PG_DIS 0x11 CONFIG_A VBAT_UV_HYS 0x13 CONFIG_C VDDIO_EN 0x14 CONFIG_D Reserved IF_BASE_ADDR1 0x30 VARIANT_ID MRC VRC 0x31 DEVICE_ID DEVICE_ID 0x32 CUSTOMER_ID CUSTOMER_ID 0x33 CONFIG_ID CONFIG_REV 0x07 AUTOBOOT SL_nONKEY_CO NT PM_IF_HSM GPIO_1_MOD E PC_DONE KEY_DELAY M_VBAT_WA RN RN TEMP_WARN VBAT_WARN E_KEY_RESE E_TEMP_WA E_VBAT_WA T RN RN PD_RESET GPI_RESET RN PVC_RAMPU P GPIO_1_TYPE I2C_TO_EN M_TEMP_WA PVC_OC_WA MSTSLV_IF_EN Reserved E_nONKEY NONKEY_RES ET DE PVC_DIS_SL Reserved GPIO_0_PIN GPIO_0_PD GPIO_0_PU GPIO_0_DEGLIT CH NONKEY_PIN M_nONKEY NONKEY_MO M_PVC_OC_WA RN nONKEY E_PVC_OC_WA RN VBAT_UV_CRIT PVC_PG_ADJ VDDIO_DIS_ PVC_SL SL PVC_MODE PVC_EN GPIO_0_MO GPIO_0_TYP DE E GPI_DEBOUNCE NONKEY_DEBOUNCE M_PVC_PG M_GPI_1 M_GPI_0 PVC_PG GPI_1 GPI_0 E_PVC_PG E_GPI_1 E_GPI_0 TEMP_CRIT POR PVC_OC_CRI T PVC_MS_HYST I_STUP_PVC VBAT_UV_CRIT_THRSH FAULT_TIME VDDIO_CONF VBAT_UV_WARN Table 15: VENDORID 0x01 Bit Mode Symbol Description Reset 7:0 R/W VENDORID Specific vendor ID. 0x0 Datasheet CFR0011-120-00 Revision 3.3 38 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 16: MODE_CTRL 0x02 Bit Mode Symbol Description Reset 7 R/W - Reserved 0x0 6 R/W AUTOBOOT 0: The cold boot from OFF stops in POWER_DOWN mode. An nONKEY press is needed to move to ACTIVE 1: The cold boot from OFF ends in ACTIVE 0x1 5 R/W RESET_CYCLE 0: A power cycle initiated by SOFTRESET stops in POWER_DOWN mode. An nONKEY press is needed to move to ACTIVE 1: A power cycle initiated by SOFTRESET ends in ACTIVE 0x1 4 R/W nONKEY_CYCLE 0: A power cycle initiated by long nONKEY press stops in POWER_DOWN mode. An nONKEY press is needed to move to ACTIVE 1: A power cycle initiated by long nONKEY press ends in ACTIVE 0x1 3 R/W MSTSLV_IF_EN 0: Standalone; GPIO_0 as per GPIO_0_PIN configuration 1: GPIO_0 is dedicated master/slave interface; GPIO_0_PIN has no effect ( Pad Deglitch settings as per GPIO_0_DEGLITCH ) 0x0 GPI0_0 == MstSlv_IF INPUT // Slave Chip else GPI0_0 == MstSlv_IF OUTPUT // Master chip or standalone 2 R/W NONKEY_MODE 0: nONKEY button MODE (pin operates as edge sensitive, active low, user button ) 1: nONKEY IC_EN MODE (operates as level driven IC enable, where nONKEY = VCORE puts chip in ACTIVE state, nONKEY = 0 V puts chip into POWER_DOWN state. 0x0 1 R/W SOFTRESET When asserted, triggers a power cycle and a reset of all internal registers, followed by an OTP read 0x0 0 R/W SLEEP Target and status of SLEEP Mode Controlled from OTP, I2C interface or from GPI if configured via GPIO_X_PIN 0x0 Table 17: SLEEP_CTRL 0x03 Bit Mode Symbol Description Reset 7:4 R/W - Reserved 0x0 3 R/W SL_nONKEY_CONT Configuration of the exit from SLEEP Mode via nONKEY press 0: nONKEY press does not cause DA9313 to exit SLEEP Mode 1: nONKEY press causes DA9313 to exit SLEEP Mode 0x0 2 R/W PVC_DIS_SL PVC enable control in SLEEP Mode: 0: no change 1: PVC disabled 0x0 Datasheet CFR0011-120-00 Revision 3.3 39 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Bit Mode Symbol Description Reset 1 R/W PVC_SL PVC operation in SLEEP Mode: 0: no change 1: automatic mode 0x0 0 R/W VDDIO_DIS_SL Control VDDIO LDO enable in SLEEP Mode: 0: no change 1: VDDIO LDO disabled 0x0 Table 18: PVC_CTRL 0x04 Bit Mode Symbol Description Reset 7:2 R/W - Reserved 0x0 1 R/W PVC_MODE 0: PVC operates in fixed frequency mode 1: PVC operates in automatic frequency mode (variable frequency) 0x1 0 R/W PVC_EN Current PVC ACTIVE configuration target and status, set via OTP load, controllable via I2C or GPI via GPIO_X_PIN 0: PVC disabled 1: PVC enabled 0x0 Table 19: GPIO_CTRL 0x05 Bit Mode Symbol Description Reset 7 R/W - Reserved 0x0 6:4 R/W GPIO_1_PIN GPIO_1 PIN assigned to: 000: GPI 001: PVC_EN (Readback available in PVC_EN register field ) 010: SLEEP_EN ( Readback available in SLEEP register field) 011: Power Cycle 100: GPO 101: Power Good 110: IRQ 111: Digital clock input 0x0 Note: GPIO_0 has priority over GPIO_1 for matching input function selections 3 R/W Datasheet CFR0011-120-00 - Reserved Revision 3.3 40 of 54 0x0 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Bit Mode Symbol Description Reset 2:0 R/W GPIO_0_PIN GPIO_0 PIN assigned to: 000: GPI 001: PVC_EN ( read-back available in PVC_EN register ) 010: SLEEP_EN ( read-back available in SLEEP register ) 011: Power Cycle 100: GPO 101: Power Good 110: IRQ 111: N/A 0x0 Note: GPIO_0 has priority over GPIO_1 for matching input function selections Note: Configuration of this register is ignored if MSTSLV_IF_EN is set Table 20: GPIO_CTRL_2 0x06 Bit Mode Symbol Description Reset 7 R/W GPIO_1_PD 0: GPI: pull-down resistor disabled No impact if defined as output port 1: GPI: pull-down resistor enabled No impact if defined as output port 0x1 6 R/W GPIO_1_PU 0: GPI: pull-up resistor disabled GPO (open drain): pull-up resistor disabled (external pull-up resistor) 1: GPI: pull-up resistor enabled GPO (open drain): pull-up resistor 0x0 5 R/W GPIO_1_MODE 0: GPI: debouncing off GPO: open drain 0x1 1: GPI: debouncing on GPO: push-pull 4 R/W GPIO_1_TYPE 0: GPI/PG/IRQ: active low GPO: low level 1: GPI/PG/IRQ: active high GPO: high level 0x1 3 R/W GPIO_0_PD 0: GPI: pull-down resistor disabled No impact if defined as output port 1: GPI: pull-down resistor enabled No impact if defined as output port 0x1 2 R/W GPIO_0_PU 0: GPI: pull-up resistor disabled GPO (open drain): pull-up resistor disabled (external pull-up resistor) 1: GPI: pull-up resistor enabled GPO (open drain): pull-up resistor 0x0 1 R/W GPIO_0_MODE 0: GPI: debouncing off GPO: open drain 1: GPI: debouncing on GPO: push-pull 0x1 0 R/W GPIO_0_TYPE 0: GPI/PG/IRQ: active low GPO: low level 1: GPI/PG/IRQ: active high GPO: high level 0x1 Datasheet CFR0011-120-00 Revision 3.3 41 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 21: INTERFACE_CTRL 0x07 Bit Mode Symbol Description Reset 7 R/W WRITE_MODE I2 C write mode 0 = Page Write mode 1 = Repeated Write mode 0x0 6 R/W PM_IF_HSM Enables continuous High Speed mode on I2C interface if asserted (no master code required) 0x0 5 R/W PC_DONE Asserted from Power Commander software after the emulated OTP read has finished, automatically cleared when leaving emulated OTP read 0x0 4 R/W I2C_TO_EN Enables automatic reset of I2C interface when clock stays low for > 35 ms 0: Disabled 1: Enabled 0x1 3 R/W GPIO_0_DEGLITCH 0: Pad Deglitching disabled 1: Pad rejects pulses < 50 ns in duration 0x0 2:0 R/W GPI_DEBOUNCE GPI signal debounce time: 000: no debounce 001: 0.125 ms 010: 1.0 ms 011: 10 ms ( default ) 100: 30 ms 101: 250 ms 110: 500 ms 111: 750 ms 0x3 Table 22: NONKEY_CTRL 0x08 Bit Mode Symbol Description Reset 7:6 R/W SHUT_DELAY Long press configuration at nONKEY for initiating a power cycle: 00: Long press function disabled 01: KEY_DELAY + 4 s 10: KEY_DELAY + 5 s 11: KEY_DELAY + 6 s 0x0 5:4 R/W KEY_DELAY KEY_DELAY threshold at nONKEY 00: 1 s 01: 1.5 s 10: 2 s 11: 7 s 0x2 3 R/W NONKEY_PIN 0: An E_nONKEY event is generated when the debounced signal from port nONKEY goes low (asserting edge). If not masked, an interrupt is signaled to the host via nIRQ 0x0 1: An E_nONKEY event is generated when the debounced signal from port nONKEY goes high (de-asserting edge). If not masked, an interrupt is signaled to the host via nIRQ Datasheet CFR0011-120-00 Revision 3.3 42 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Bit Mode Symbol Description Reset 2:0 R/W NONKEY_DEBOUN CE nONKEY signal debounce time: 000: no debounce 001: 0.125 ms 010: 1.0 ms 011: 10 ms 100: 30 ms 101: 250 ms 110: 500 ms 111: 750 ms 0x3 Table 23: MASK 0x09 Bit Mode Symbol Description Reset 7 R/W - Reserved 0x0 6 R/W M_TEMP_WARN Mask for thermal warning event TEMP_WARN 0x0 5 R/W M_VBAT_WARN Mask for under voltage warning event E_VBAT_WARN 0x0 4 R/W M_nONKEY Mask for nONKEY event E_nONKEY 0x0 3 R/W M_PVC_OC_WARN Mask for PVC current warning event E_PVC_OC_WARN 0x0 2 R/W M_PVC_PG Mask for power good loss at PVC event E_PVC_PG 0x0 1 R/W M_GPI_1 Mask for GP1_1 event E_GPI_1 0x0 0 R/W M_GPI_0 Mask for GP1_0 event E_GPI_0 0x0 Table 24: STATUS 0x0A Bit Mode Symbol Description Reset 7 R PVC_OC_WARN Asserted as long as the PVC current reached the alarm threshold 0x0 6 R TEMP_WARN Asserted as long as the thermal warning threshold is reached 0x0 5 R VBAT_WARN Asserted as long as the battery under voltage warning is reached 0x0 4 R/W Reserved 0x0 3 R nONKEY Asserted as long nONKEY is pressed (low level) 0x0 2 R PVC_PG Asserted as long as the PVC output voltage is in range 0x0 1 R GPI_1 GPI_1 Level 0x0 0 R GPI_0 GPI_0 Level 0x0 Revision 3.3 08-Jun-2020 Datasheet CFR0011-120-00 43 of 54 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 25: EVENT 0x0B Bit Mode Symbol Description Reset 7 RW1C E_KEY_RESET A long press of nONKEY has been detected. DA9313 will power cycle in 1 s unless this bit is cleared by the host 0x0 6 RW1C E_TEMP_WARN TEMP_WARN caused an event 0x0 5 RW1C E_VBAT_WARN VBAT_WARN caused an event 0x0 4 RW1C E_nONKEY nONKEY caused an event 0x0 3 RW1C E_PVC_OC_WARN PVC current alarm caused an event. 0x0 2 RW1C E_PVC_PG Power good loss at PVC caused an event 0x0 1 RW1C E_GPI_1 GPI_1 event according to active state setting 0x0 0 RW1C E_GPI_0 GPI_0 event according to active state setting 0x0 Table 26: FAULT_LOG 0x0C Bit Mode Symbol Description Reset 7 R/W PVC_RAMPUP PVC has failed to ramp output voltage on start-up. Critical fault. 0x0 6 R/W PD_RESET Power cycle initiated via SOFTRESET write 0x0 5 R/W GPI_RESET Power cycle initiated by PWC GPI reset 0x0 4 R/W NONKEY_RESET Power cycle due to long press of nONKEY 0x0 3 R/W VBAT_UV_CRIT Input under voltage triggered a fault condition 0x0 2 R/W PVC_OC_CRIT PVC over-current triggered a fault condition 0x0 1 R/W TEMP_CRIT Junction over-temperature triggered a fault condition 0x0 0 R/W POR Power up from OFF (cold boot) 0x0 Table 27: LOCK_REG 0x0D Bit Mode Symbol Description Reset 7:0 R/W LOCK_REG Soft lock for registers from 0x0E to 0x2F 0x4A Writing to registers in this region while the region is LOCKED has no effect Region will default to LOCKED (LOCK_REG readback value 0) Writing the key (documented as the reset value ) will UNLOCK the region Writing any value other than the key will LOCK the region from 0x0E to 0x2F Datasheet CFR0011-120-00 Revision 3.3 44 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 28: PVC_CONFIG_1 0x0E Bit Mode Symbol Description Reset 7:6 R/W PVC_DROP VDROP: drop from VBAT/2 at which VOUT, when increasing and crossing (VBAT/2-VDROP) (so becoming greater), generates a transition to DCM 00: 20 mV 01: 30 mV 10: 40 mV (default) 11: 50 mV 0x2 5:4 R/W PVC_HYST VHYST: hysteresis on the VDROP to go back to CCM. So when VOUT is decreasing and crosses (VBAT/2-VDROP-VHYST) (so becoming lower), it generates a transition back to DCM. 00: 0 V 01: 10 mV 10: 20 mV (default) 11: 30 mV. 0x2 3:2 R/W PVC_MS_DROP Definition of four levels at which the master triggers the slave request. VMSI referenced to VCCM, where VCCM = (VBAT/2-PVC_DROP-PVC_HYSTMAX): 0x1 00: 15 mV below VCCM 01: 30 mV below VCCM (default) 10: 45 mV below VCCM 11: 60 mV below VCCM Note HYSTMAX is a constant value of 30 mV. 1:0 R/W PVC_MS_HYST MSI comparator hysteresis 0x1 00: 0 mV above VMSI 01: 15 mV above VMSI (default) 10: 30 mV above VMSI 11: 45 mV above VMSI Table 29: PVC_CONFIG_2 0x0F Bit Mode Symbol Description Reset 7:6 R/W PVC_SLV_IF_PHASE In master/slave configuration a clock is generated to control the slave interface. This clock has a configurable phase offset to the PVC_CLOCK: 0: 0° 1: 90° 2: 180° 3: 270° 0x0 5:4 R/W - Reserved 0x1 Datasheet CFR0011-120-00 Revision 3.3 45 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Bit Mode Symbol Description Reset 3:0 R/W PVC_ILIM Note: PVC recommended max value is 10 A. PVC peak current limit. 0000: 4800 mA 0001: 5250 mA 0010: 5700 mA 0011: 6150 mA 0100: 6600 mA 0101: 7050 mA 0110: 7500 mA 0111: 7950 mA 1000: 8400 mA 1001: 8850 mA 1010: 9300 mA 1011: 9750 mA 1100: 10200 mA 1101: 10650 mA 1110: 11100 mA 1111: 11550 mA 0xC Table 30: PVC_CONFIG_3 0X10 Bit Mode Symbol Description Reset 7 R/W PVC_PG_DIS 0: PVC power good comparator enabled 1: PVC power good comparator disabled 0x0 This setting must be static and cannot be reconfigured in the application. 6:2 R/W PVC_PG_ADJ 00000: 2.50 V 00001: 2.60 V 00010: 2.70 V 0x5 00101: 3.00 V 11000: 4.90 V 11001: 5.00 V >11001: 5.00 V 1:0 R/W Datasheet CFR0011-120-00 I_STUP_PVC PVC start up current 00: 500 mA 01: 1000 mA 10: 1500 mA 11: 2000 mA Revision 3.3 46 of 54 0x3 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 31: CONFIG_A 0x11 Bit Mode Symbol Description Reset 7:5 R/W VBAT_UV_HYS Programmable hysteresis for the critical undervoltage threshold: 0x3 000: 50 mV 001: 100 mV 010: 150 mV 011: 200 mV 100: 250 mV 101: 300 mV 110: 350 mV 111: 400 mV 4:0 R/W VBAT_UV_CRIT_TH RSH Note: PVC design requires 5.0 V minimum setting for correct operation: 0x0 00000: 4.60 V 00001: 4.65 V 00010: 4.70 V 00011: 4.75 V 01000: 5.00 V 11100: 6.00 V 11101: 6.05 V 11110: 6.10 V 11111: 6.15 V Table 32: CONFIG_C 0x13 Bit Mode Symbol Description Reset 7 R/W VDDIO_EN 0: VDDIO LDO disabled, pads supplied from VCORE 1: VDDIO LDO enabled, pads supplied at level set via VDDIO_CONF 0x1 Note: When VDDIO_EN == 0, open drain GPO configurations via GPIO_1_PIN or GPIO_0_PIN valid only 6:5 R/W FAULT_TIME System controller configurable, pause when power cycling to ensure discharge of all critical nodes in the application before any attempt to reboot. 00: 0 ms (wait disable) 01: 10 ms 10: 100 ms 11: 500 ms 0x2 4:3 R/W VDDIO_CONF Selects the internal generated VDDIO voltage: 00: 1.5 V 01: 1.8 V 10: 2.8 V 11: 3.3 V 0x3 Datasheet CFR0011-120-00 Revision 3.3 47 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Bit Mode Symbol Description Reset 2:0 R/W VBAT_UV_WARN 000: 5.2 V 001: 5.4 V 010: 5.6 V 011: 5.8 V 100: 6.0 V 101: 6.2 V 110: 6.4 V 111: 6.6 V 0x1 Table 33: CONFIG_D 0x14 Bit Mode Symbol Description Reset 7:4 R/W - Reserved 0xC 3:0 R/W IF_BASE_ADDR1 I2C uses slave address as follows: IF_BASE_ADDR1 = 4 MSBs of 7 Bit I2C slave address (XXXX000) 0xD Example: For code XXXX = 1101 110_1000: Slave address of I2C interface = 0x68. Table 34: VARIANT_ID 0x30 Bit Mode Symbol Description Reset 7:4 R/W MRC Read-back of mask revision code (MRC) -code 0 to AA die release 0x0 3:0 R/W VRC Read-back of package variant code (VRC) -indicates type of package option 0x0 Table 35: DEVICE_ID 0x31 Bit Mode Symbol Description Reset 7:0 R DEVICE_ID Device ID: 0x81 0x81 Table 36: CUSTOMER_ID 0x32 Bit Mode Symbol Description Reset 7:0 R/W CUSTOMER_ID ID for customer and target application platform, written during production of variant 0x0 Datasheet CFR0011-120-00 Revision 3.3 48 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Table 37: CONFIG_ID 0x33 Bit Mode Symbol Description Reset 7:0 R/W CONFIG_REV ID for revision of OTP settings, written during production of variant 00000000 - OTP unconfigured (reserved) >00000000 - OTP configuration revision xxx 0x0 Datasheet CFR0011-120-00 Revision 3.3 49 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 14 Package Information 14.1 Package Outline Figure 21: 43 WLCSP Package Outline Drawing Datasheet CFR0011-120-00 Revision 3.3 50 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 14.2 Moisture Sensitivity Level The Moisture Sensitivity Level (MSL) is an indicator for the maximum allowable time period (floor lifetime) in which a moisture sensitive plastic device, once removed from the dry bag, can be exposed to an environment with a specified maximum temperature and a maximum relative humidity before the solder reflow process. The MSL classification is defined in Table 38. For detailed information on MSL levels refer to the IPC/JEDEC standard J-STD-020, which can be downloaded from http://www.jedec.org. The WLCSP package is qualified for MSL 1. Table 38: MSL Classification MSL Level Floor Lifetime Conditions MSL 4 72 hours 30 °C / 60 % RH MSL 3 168 hours 30 °C / 60 % RH MSL 2A 4 weeks 30 °C / 60 % RH MSL 2 1 year 30 °C / 60 % RH MSL 1 Unlimited 30 °C / 85 % RH 14.3 WLCSP Handling Manual handling of WLCSP packages should be reduced to the absolute minimum. In cases where it is still necessary, a vacuum pick-up tool should be used. In extreme cases plastic tweezers could be used, but metal tweezers are not acceptable, since contact may easily damage the silicon chip. Removal of a WLCSP package will cause damage to the solder balls. Therefore a removed sample cannot be reused. WLCSP packages are sensitive to visible and infrared light. Precautions should be taken to properly shield the chip in the final product. 14.4 Soldering Information Refer to the IPC/JEDEC standard J-STD-020 for relevant soldering information. This document can be downloaded from http://www.jedec.org. Datasheet CFR0011-120-00 Revision 3.3 51 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 15 Layout Guidelines 15.1 Suggested PCB Layout VBAT GND VOUT Route 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 0402 PGND VBAT VCORE PGND C2N PGND AGND PGND C1N C2N VOUT_S C1N 250 µm C2N VOUT VOUT C1N VOUT VOUT VOUT 250 µm 250 µm VOUT 0402 0603 BS2 VOUT VOUT BS1 0603 250 µm 250 µm 0603 0603 0402 C2P VOUT VOUT C1P C2P 250 µm 250 µm C1P C2P VIN VIN C1P VIN SDA SCL VIN 0402 0402 VIN GPIO_1 GPIO_0 VIN 0402 0402 nOnkey 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm 250 µm Figure 22: Suggested PCB Layout The concept of PCB layout is presented in Figure 22. All drawn layers are top layer. Standard PTH VIAs connect the top layer to underlying VBAT, VOUT and GND plane(s). 15.2 RouteEasyTM Technology Chart BGA ball diameter: 0.27 mm (10 mil) BGA land size: 0.25 mm (10 mil) Via hole size (finished): ≤ 0.2 to 0.25 mm (8 to 10 mil) Via pad size: ≤ 0.55 mm (22 mil) Anti-pad size: ≤ 0.75 mm (30 mil) Trace width: 0.1 mm (4 mil) Trace/trace space: 0.1 mm (4 mil) Trace/pad/land space: ≥ 0.075 mm (3 mil) Datasheet CFR0011-120-00 Revision 3.3 52 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider 16 Application Information The following recommended components are examples selected from requirements of a typical application. 16.1 Recommended Capacitors Ceramic capacitors are used as bypass capacitors at input and output rails as well as flying capacitors for the PVC. When selecting a capacitor the DC bias characteristic has to be taken into account. For the flying capacitors the temperature rise from maximum ripple current must be considered. Table 39: Recommended Capacitor Types Application Value Size Temp Char Tol (%) Rated V Type PVC flying CFLY 4x 47 µF 0603 X5R ± 15 % ± 20 6.3 V Murata GRM188R60J476ME15 4x 47 µF 0805 X5R ± 15 % ± 20 6.3 V Murata GRM21BR60J476ME11 1x 4.7 µF 0402 X5R ± 15 % ± 20 10 V Murata GRM155R61A475MEAA PVC bootstrap 2x 10 nF 0402 X7R ± 15 % ± 10 16 V Murata GRM15XR71C103KA86 CBS_PVC 2x 10 nF 0201 X7R ± 15 % ± 10 10 V Murata GRM033R71A103KA01 VCORE output bypass 1x 2.2 µF 0402 X5R ± 15 % ± 20 6.3 V Murata GRM155R60J225ME95 2x 4.7 µF 0402 X5R ± 15 % ± 20 16 V Murata GRM155R61C475ME15 PVC bypass CO_PVC CO_VCORE PVC input decoupling CIN_PVC 17 Ordering Information The order number consists of the part number followed by a suffix indicating the packing method. For details, please consult the customer portal on our web site or your local sales representative. Table 40: Ordering Information Part Number (Note 1) Package Name Package Description Package Outline DA9313-xxVK2 43 WLCSP Tape and reel (7500 pcs) Figure 21 DA9313-xxVK6 43 WLCSP Waffle tray Figure 21 Note 1 xx is the OTP variant Datasheet CFR0011-120-00 Revision 3.3 53 of 54 08-Jun-2020 © 2020 Dialog Semiconductor DA9313 High Efficiency Dual Cell Switched Capacitor Divider Status Definitions Revision Datasheet Status Product Status Definition 1. Target Development This datasheet contains the design specifications for product development. Specifications may be changed in any manner without notice. 2. Preliminary Qualification This datasheet contains the specifications and preliminary characterization data for products in pre-production. Specifications may be changed at any time without notice in order to improve the design. 3. Final Production This datasheet contains the final specifications for products in volume production. The specifications may be changed at any time in order to improve the design, manufacturing and supply. Major specification changes are communicated via Customer Product Notifications. Datasheet changes are communicated via www.dialog-semiconductor.com. 4. Obsolete Archived This datasheet contains the specifications for discontinued products. The information is provided for reference only. Disclaimer Unless otherwise agreed in writing, the Dialog Semiconductor products (and any associated software) referred to in this document are not designed, authorized or warranted to be suitable for use in life support, life-critical or safety-critical systems or equipment, nor in applications where failure or malfunction of a Dialog Semiconductor product (or associated software) can reasonably be expected to result in personal injury, death or severe property or environmental damage. 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RoHS Compliance Dialog Semiconductor’s suppliers certify that its products are in compliance with the requirements of Directive 2011/65/EU of the European Parliament on the restriction of the use of certain hazardous substances in electrical and electronic equipment. RoHS certificates from our suppliers are available on request. Contacting Dialog Semiconductor United Kingdom (Headquarters) Dialog Semiconductor (UK) LTD Phone: +44 1793 757700 North America Dialog Semiconductor Inc. Phone: +1 408 845 8500 Hong Kong Dialog Semiconductor Hong Kong Phone: +852 2607 4271 China (Shenzhen) Dialog Semiconductor China Phone: +86 755 2981 3669 Germany Dialog Semiconductor GmbH Phone: +49 7021 805-0 Japan Dialog Semiconductor K. K. Phone: +81 3 5769 5100 Korea Dialog Semiconductor Korea Phone: +82 2 3469 8200 China (Shanghai) Dialog Semiconductor China Phone: +86 21 5424 9058 The Netherlands Dialog Semiconductor B.V. Phone: +31 73 640 8822 Taiwan Dialog Semiconductor Taiwan Phone: +886 281 786 222 Email: enquiry@diasemi.com Web site: www.dialog-semiconductor.com Datasheet CFR0011-120-00 Revision 3.3 54 of 54 08-Jun-2020 © 2020 Dialog Semiconductor
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