AS3709 μPMIC with 5 DCDC and 2 LDOs General Description The AS3709 is an ultra compact μPMIC containing 5 high-efficiency, constant-frequency synchronous buck converters in addition with two universal IO LDOs are available for lower current power rails. The wide input voltage range (2.7V to 5.5V), automatic power-save mode and minimal external component requirements make the AS3709 perfect for any single Li-Ion battery-powered or fixed 3.3V/5V supply application. Typical supply current with no load is 110μA and decreases to ≤ 7μA in shutdown mode. An internal synchronous switch increases efficiency and eliminates the need for an external Schottky diode. The internally fixed switching frequency (2MHz, 3MHz or 4MHz) allows the use of small surface mount external components. Very low output voltages can be delivered with the internal 0.6V feedback reference voltage. The AS3709 is available in a 32-pin QFN 4x4mm package and in a very compact CSP36 with 0.4mm pitch. For further understanding in regards to the contents of the datasheet, please refer to the Reference Guide located at the end of the document. Key Benefits & Features The benefits and features of AS3709, μPMIC with 5 DCDC and 2 LDOs are listed below: Figure 1: Added Value of using AS3709 Benefits Features Compact design due to small coils for IO and memory voltage generation 5 DCDC step down regulators (2-4MHz) Independent voltage rails for general purpose IO supplies 2 universal IO LDOs Flexible and fast adaptation to different processors/applications OTP programmable Boot and Power-down sequence Power saving control according to the processor‘s needs. Stand-by function with programmable sequence and voltages Self-contained start-up and control for single-cell battery applications. Safety shutdown feature. Control Interface I²C/SPI control lines ON key with 4/8s emergency shut-down POR with RESET I/O Dedicated packages for specific applications. Optimization for PCB cost or size. 32-pin QFN (4x4mm), 0.4mm pitch 36-ball WL-CSP 0.4mm pitch ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 1 Applications The device is ideal for: • SSDs, mobile communication devices • Laptops and PDAs • Ultra-low-power systems • Medical instruments or any other space-limited application with low power-consumption requirements. Block Diagram The functional blocks of this device for reference are shown below: Figure 2: AS3709 Block Diagram VSUP VIN_LDO1 LDO1 2.2uF 2.2uF VSUP_SD1 VSUP 2.2uF VSS_LDO1 DCDC1 LDO1 PMOS 0.6 0.7 – 1A 0.6 – 3.35V 2 – 4MHz 0.8 – 3.3V 300mA LX_SD1 FB_SD1 SD1 1uH 10uF PVSS_SD1 VSUP AS3709 VSUP VIN_LDO2 LDO2 2.2uF 2.2uF VSS_LDO2 LDO2 PMOS 0.6 DCDC2 0.7 – 1A 0.6 – 3.35V 2 – 4MHz 0.8 – 3.3V 300mA SCLK 1uF V2_5 VSSA AS3709 – 2 LX_SD3 10uF 2.2uF FB_SD3 GPIOs 10uF PVSS_SD3 VSUP DCDC4 System Control & Reference SD3 1uH 2.2uF VSUP_SD4 0.7 – 1A 0.6 – 3.35V 2 – 4MHz Supervisor (Supply & Temp) GPIO1 GPIO2 SD2 1uH PVSS_SD2 POR ON XRES FB_SD2 VSUP 0.7 – 1A 0.6 – 3.35V 2 – 4MHz I2C LX_SD2 VSUP_SD3 DCDC3 SDA 2.2uF VSUP_SD2 BOOT ROM OTP LX_SD4 FB_SD4 SD4 1uH 10uF PVSS_SD4 VSUP 2.2uF VSUP_SD5 DCDC5 0.7 – 1A 0.6 – 3.35V 2 – 4MHz LX_SD5 FB_SD5 1uH SD5 10uF PVSS_SD5 ams Datasheet, Confidential: 2013-Aug [1-02] Pi n A s s i g n m e n t Pin Assignment The AS3709 pin assignments are described below. Figure 3: 36 balls WL-CSP with 0.4mm Pitch Ball Assignments: Shows the top view ball assignment of the AS3709 WL-CSP. Pin A1 indicator A1 SCL A2 XRES A3 GPIO2 A4 VSSA A5 PVSS SD5 B1 V2_5 B2 SDA B3 ON B4 FB_SD5 B5 LX_SD5 B6 VSUP SD5 C1 VSUP SD1 C2 LX_SD1 C3 FB_SD1 C4 GPIO1 C5 FB_SD4 C6 LX_SD4 D2 PVSS SD1 D3 LDO1 D4 LDO2 D5 PVSS SD4 E2 LX_SD2 E3 FB_SD2 E4 FB_SD3 E5 LX_SD3 F2 PVSS SD2 F3 VIN LDO1 F4 VIN LDO2 F5 PVSS SD3 E1 VSUP SD2 E6 VSUP SD3 ams Datasheet, Confidential: 2013-Aug [1-02] PVSS_SD5 FB_SD5 VSSA GPIO1 GPIO2 XRES ON SDA 31 30 29 28 27 26 25 Pin Assignment: Shows the top view pin assignment of the AS3709 QFN package. 32 Figure 4: 32 pins QFN 4x4 with 0.4mm Pitch LX_SD5 1 24 SCL VSUP_SD5 2 23 V2_5 VSUP_SD4 3 AS3709 22 VSUP_SD1 LX_SD4 4 QFN 32-pin 4x4mm 21 LX_SD1 PVSS_SD4 5 Exposed Pad: GND 20 PVSS_SD1 FB_SD4 6 19 FB_SD1 VSUP_SD3 7 18 VSUP_SD2 LX_SD3 8 17 LX_SD2 9 10 11 12 13 14 15 16 PVSS_SD3 FB_SD3 VIN_LDO2 LDO2 LDO1 VIN_LDO1 FB_SD2 PVSS_SD2 33 AS3709 – 3 Pin Assignment Figure 5: Pin Description Pin Number Pin Name Pin Type B5 LX_SD5 DIG OUT DCDC SD5 switch output to coil Open 2 B6 VSUP_SD5 SUP IN DCDC SD5 pos supply terminal Always needed 3 B6 VSUP_SD4 SUP IN DCDC SD4 pos supply terminal Always needed 4 C6 LX_SD4 DIG OUT DCDC SD4 switch output to coil Open 5 D5 PVSS_SD4 GND DCDC SD4 neg supply terminal Always needed 6 C5 FB_SD4 ANA IN DCDC SD4 Feedback pin Open 7 E6 VSUP_SD3 SUP IN DCDC SD3 pos supply terminal Always needed 8 E5 LX_SD3 DIG OUT DCDC SD3 switch output to coil Open 9 F5 PVSS_SD3 GND DCDC SD3 neg supply terminal Always needed 10 E4 FB_SD3 ANA IN DCDC SD3 Feedback pin Open 11 F4 VIN_LDO2 SUP IN Supply pin for LDO2 Always needed 12 D4 LDO2 ANA OUT Output Voltage of LDO2 Open 13 D3 LDO1 ANA OUT Output Voltage of LDO1 Open 14 F3 VIN_LDO1 SUP IN Supply pin for LDO1 Always needed 15 E3 FB_SD2 ANA IN DCDC SD2 Feedback pin Open 16 F2 PVSS_SD2 GND DCDC SD2 neg supply terminal Always needed 17 E2 LX_SD2 DIG OUT DCDC SD2 switch output to coil Open 18 E1 VSUP_SD2 SUP IN DCDC SD2 pos supply terminal Always needed 19 C3 FB_SD1 ANA IN DCDC SD1 Feedback pin Open 20 D2 PVSS_SD1 GND DCDC SD1 neg supply terminal Always needed 21 C2 LX_SD1 DIG OUT DCDC SD1 switch output to coil Open 22 C1 VSUP_SD1 SUP IN DCDC SD1 pos supply terminal Always needed 23 B1 V2_5 ANA OUT Internal 2.5V regulator output Always needed 24 A1 SCL DIG IN 2-wire Serial IF Clock Input Open 25 B2 SDA DIG IO 2-wire Serial IF Data IO Open 26 B3 ON DIG IN Power Up Input Open 27 A2 XRES DIG IO Reset IO, external pull-up resistor needed Always needed QFN WLP 1 AS3709 – 4 Description If not Used ams Datasheet, Confidential: 2013-Aug [1-02] Pi n A s s i g n m e n t Pin Number Pin Name Pin Type A3 GPIO2 ANA IO General Purpose IO 2 Open 29 C4 GPIO1 ANA IO General Purpose IO 1 Open 30 A4 VSSA GND GND Reference for analog blocks Always needed 31 B4 FB_SD5 ANA IN DCDC SD5 Feedback pin Open 32 A5 PVSS_SD5 GND DCDC SD5 neg supply terminal Always needed VSS GND Exposed Pad Always needed QFN WLP 28 33 ams Datasheet, Confidential: 2013-Aug [1-02] Description If not Used AS3709 – 5 Absolute Maximum Ratings Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated under “Operating Conditions” is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Absolute Maximum Ratings Figure 6: Absolute Maximum Ratings Symbol Parameter Min Max Units Comments Electrical Parameters Supply Voltage to Ground 5V pins -0.5 7.0 V Applicable for pins: VSUP_SDx, VIN_LDOx, SCLK, SDA, ON, XRES, GPIOx, LX_SDx Supply Voltage to Ground 3V pins -0.5 5.0 V Applicable for pins: V2_5, LDOx, FB_SDx Voltage Difference between Ground Terminals -0.3 0.3 V Applicable for pins: VSSA, PVSS_SDx, Exposed Pad Input Current (latch-up immunity) -100 100 mA Norm: JEDEC JESD78 Continuous Power Dissipation (TA = +70°C) PT 1.2 W PT (1) for QFN32 package (RTHJA ~ 45K/W) 1.1 W PT (1) for WL-CSP36 package (RTHJA ~ 50K/W) Continuous power dissipation Electrostatic Discharge VESD-HBM Electrostatic Discharge HBM ±2 kV Norm: JEDEC JESD22-A114F Temperature Ranges and Storage Conditions TAMB TJ Operating Temperature Junction Temperature +85 °C +125 °C Storage Temperature Range -55 +150 °C QFN Storage Temperature Range -55 +125 °C WL-CSP 85 % Humidity non-condensing AS3709 – 6 -40 ams Datasheet, Confidential: 2013-Aug [1-02] Absolute Maximum Ratings Symbol Parameter Min Max Units Comments Temperature (Soldering) TBODY Package Body Temperature +260 °C 32-pin QFN: Norm IPC/JEDEC J-STD-020 (2) The lead finish for Pb-free leaded packages is matte tin (100% Sn) TBODY Package Body Temperature +260 °C 36-ball WL-CSP: Norm IPC/JEDEC J-STD-020 (2) MSLQFN Moisture Sensitive Level 3 Represents a maximum floor life time of 168h MSLWL-CSP Moisture Sensitive Level 1 Represents an unlimited floor life time Note(s) and/or Footnote(s): 1. Depending on actual PCB layout and PCB used. 2. The reflow peak soldering temperature (body temperature) is specified according IPC/JEDEC J-STD-020 “Moisture/Reflow Sensitivity Classification for Non hermetic Solid State Surface Mount Devices ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 7 Electrical Characteristics Electrical Characteristics All limits are guaranteed. The parameters with min and max values are guaranteed with production tests or SQC (Statistical Quality Control) methods. Figure 7: Electrical Characteristics Symbol Parameter Conditions Min Typ VIN Input Voltage range Pin VSUP IQ Quiescent Current Normal operating current. With bit Low_power_on = 0; only V2_5 active 155 ILOWPOWER Low-Power Quiescent Current Normal operating current. With bit Low_power_on = 1; only V2_5 active 110 IPOWEROFF Shutdown Current With bit power_off = 1; only V2_5 is active in power OFF mode. Not tested, guaranteed by design 7 2.7 Max Unit 5.5 V 200 μA 20 Electrical Characteristics: VSUP = 3.7V, VOUT < VIN – 0.5V, TAMB = -40°C to +85°C, typ. values @ TAMB = +25°C (unless otherwise specified) AS3709 – 8 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s Detailed Description Power Management Functions Step Down DCDC Converter The step-down converter is a high-efficiency fixed frequency current mode regulator. By using low resistance internal PMOS and NMOS switches, efficiency up to 95% can be achieved. The fast switching frequency allows using small inductors, without increasing the current ripple. The unique feedback and regulation circuit guarantees optimum load and line regulation over the whole output voltage range, up to an output current of 1A, with an output capacitor of only 10μF. The implemented current limitation protects the DCDC Converter and the coil during overload condition. Figure 8: Step Down DC/DC Converter Block Diagram IMIN Sd_low_noise 250mA + - Clk VSUP 1.2A + 2.2uF ILIMIT ISENSEP Overvoltage Comparator + - Ref + 8% 1uH Logic LX_SD 10uF + Ref - 5% VOUT - S ISENSEN + VSS_SD Zero Comparator Skip + PWM Comparator - Sd_lv Ref = 0.6V FB_SD buck_v Slope Compensation Softstart ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 9 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Mode Settings To allow optimized performance in different applications, there are bit settings possible, to get the best compromise between high efficiency and low input/output ripple. Low-Ripple, Low-Noise Operation Low-ripple, low-noise operation can be enabled by setting bit sd_low_noise = 1. In this mode there is no minimum coil current necessary before switching OFF the PMOS. As long as the load current is superior to the ripple current, the device operates in continuous mode. When the load current gets lower, the discontinuous mode is triggered. Resultant the auto-zero comparator stops the NMOS conduction to avoid load discharger and the duty cycle is reduced down to tMIN_ON to keep the regulation loop stable. This results in a very low ripple and noise, but decreased efficiency at light loads, especially at low input to output voltage differences. Only in the case the load current gets so small, that less than the minimum on time of the PMOS would be needed to keep the loop in regulation, the regulator will enter low power mode operation. The crossover point is about 15mA for V IN = 3V, V OUT = 1.2V, 1μH, 4MHz. Figure 9: DC/DC Buck Low Noise Mode DC/DC buck burst mode: Shows the DC/DC switching waveforms for low noise operation. coil current (200mA/div) LX (2V/div) VOUT (50mV/div) time (5us/div) High-Efficiency Operation (Default Setting) High-efficiency operation is enabled by setting bit sd_low_noise = 0. In this mode there is a minimum coil current necessary before switching OFF the PMOS. Resultant there are less pulses AS3709 – 10 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s necessary at low output loads, and therefore the efficiency increases. As drawback, this mode increases the ripple up to a higher output current. The crossover point to low power mode is already reached at reasonable high output currents. (e.g. @110mA for V IN = 3V, V OUT = 1.2V, 1μH, 4MHz) Figure 10: DC/DC Buck High Efficiency Mode DC/DC buck burst mode: Shows the DC/DC switching waveforms for high efficiency operation coil current (200mA/div) LX (2V/div) VOUT (50mV/div) time (20us/div) Low Power Mode Operation (Automatically Controlled) As soon as the output voltage stays above the desired target value for a certain time, some internal blocks will be powered down leaving the output floating to lower the power consumption. Normal operation starts as soon as the output drops below the target value for a similar amount of time. To minimize the accuracy error some internal circuits are kept powered to assure a minimized output voltage ripple. Two addition guard bands, based on comparators, are set at ±5% of the target value to react quickly on large over/undershoots by immediately turning on the output drivers without the normal time delays. This ensures a minimized ripple also in very extreme load conditions. DVM (Dynamic Voltage Management) To minimize the over-/undershoot during a change of the output voltage, the DVM can be enabled. With DVM the output voltage will ramp up/down with a selectable slope after the new value was written to the registers. Without DVM the slew rate of the output voltage is only determined by external components like the coil and load capacitor as well as the load current. DVM can be selected for all step-down converters, but only for one at a time. (see sd_dvm_select and dvm_time description) ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 11 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Fast Regulation Mode This mode can be used to react faster on sudden load changes and thus minimize the over-/undershoot of the output voltage. This mode needs a 22uF output capacitor instead the 10uF one to guarantee the stability of the regulator. The mode is enabled by setting sd_fast =1. Selectable Frequency Operation Especially for very low load conditions, e.g. during a sleep mode of a processor, the switching frequency can be reduced to achieve a higher efficiency. The frequency can be set to 2, 3 or 4MHz and this mode is selected by setting sd_freq and sd_fsel to the appropriate values. 100% PMOS ON Mode for Low Dropout Regulation For low input to output voltage difference the DCDC converter can use 100% duty cycle for the PMOS transistor, which is then in LDO mode. Step Down Converter Configuration Modes The step down dc/dc converters have two configuration modes to deliver different output currents for the applications. The operating mode is selected by setting the bit sd2_slave, sd4_slave and sd5_slave (the default is set by the Boot-OTP). Figure 11: DCDC Step Down Normal Operating Mode VSUP SD1 0.6 – 3.3V 0.7 – 1A VSUP VSUP_SD1 2.2 uF LX_SD1 1uH 10uF FB_SD1 PVSS_SD1 DCDC DCDC Step Down 1 Step Down 3 SD2 0.6 – 3.3V 0.7 – 1A FB_SD3 10uF 1 uH 10 uF PVSS_SD3 VSUP LX_SD2 FB_SD2 PVSS_SD2 2 .2uF VSUP_SD4 VSUP_SD2 1uH SD3 0.6 – 3.3V 0.7 – 1A LX_ SD3 VSUP 2.2 uF 2 .2uF VSUP_SD3 DCDC DCDC Step Down 2 Step Down 4 SD4 0.6 – 3.3V 0.7 – 1A LX_ SD4 FB_SD4 1 uH 10uF PVSS_SD4 VSUP 2 .2uF VSUP_SD5 5 x 1A DCDC Step Down 5 LX_ SD5 FB_SD5 PVSS_SD5 SD5 0.6 – 3.3V 0.7 – 1A 1 uH 10uF Normal Operating Mode: sd2_slave = 0, sd4_slave = 0, sd5_slave = 0 AS3709 – 12 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s Figure 12: DCDC Step Down SD3/SD4 Operating Mode VSUP SD1 0.6 – 3.3V 0.7 – 1A VSUP VSUP_SD1 2.2 uF LX_SD1 1uH 10uF FB_SD1 PVSS_SD1 2.2uF VSUP_SD3 DCDC DCDC Step Down 1 Step Down 3 1uH FB_SD3 10uF PVSS_SD3 SD2 0.6 – 3.3V 0.7 – 1A VSUP_SD2 1uH 10uF 10uF VSUP VSUP 2.2 uF SD 3 0.6 – 3.3V 1.4 – 2A LX_SD3 VSUP_SD4 LX_SD2 FB_SD2 PVSS_SD2 DCDC DCDC Step Down 2 Step Down 4 LX_SD4 2 .2uF FB_SD4 PVSS_SD4 VSUP 3 x 1A 1 x 2A 2.2uF VSUP_SD5 DCDC Step Down 5 LX_SD5 FB_SD5 SD5 0.6 – 3.3V 0.7 – 1A 1uH 10uF PVSS_SD5 SD3/SD4 Operating Mode: sd2_slave = 0, sd4_slave = 1, sd5_slave = 0 Figure 13: DCDC Step Down SD1/SD2 & SD3/SD4 Operating Mode VSUP VSUP VSUP_SD1 2. 2uF SD1 0.6 – 3.3V 1.4 – 2A LX_SD1 1uH 10uF 10 uF FB_SD1 PVSS_SD1 2.2uF VSUP_SD3 DCDC DCDC Step Down 1 Step Down 3 1uH FB_SD3 10uF PVSS_ SD3 VSUP 10uF VSUP VSUP_SD2 2.2uF SD 3 0.6 – 3.3V 1.4 – 2A LX_SD3 LX_SD2 FB_SD2 PVSS_SD2 VSUP_SD4 DCDC DCDC Step Down 2 Step Down 4 LX_SD4 2.2uF FB_SD4 PVSS_ SD4 VSUP 1 x 1A 2 x 2A 2.2uF VSUP_SD5 DCDC Step Down 5 LX_SD5 FB_SD5 1uH PVSS_ SD5 SD5 0.6 – 3.3V 0.7 – 1A 10uF SD3/SD4 & SD4/SD5 Operating Mode: sd2_slave = 1, sd4_slave = 1, sd5_slave = 0 ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 13 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Figure 14: DCDC Step Down SD3/SD4/SD5 Operating Mode VSUP SD1 0.6 – 3.3V 0.7 – 1A VSUP VSUP_SD1 2.2 uF LX_SD1 1uH FB_SD1 10uF PVSS_SD1 2.2uF VSUP_SD3 DCDC DCDC Step Down 1 Step Down 3 1uH FB_SD3 10uF PVSS_SD3 SD2 0.6 – 3.3V 0.7 – 1A VSUP_SD2 LX_SD2 1uH FB_SD2 10uF 22uF VSUP VSUP 2.2 uF SD 3 0.6 – 3.3V 2.1 – 3A LX_SD3 PVSS_SD2 VSUP_SD4 LX_SD4 DCDC DCDC Step Down 2 Step Down 4 2 .2uF FB_SD4 PVSS_SD4 VSUP VSUP_SD5 2 x 1A LX_SD5 DCDC Step Down 5 1 x 3A FB_SD5 2.2uF PVSS_SD5 SD3/SD4/SD5 Operating Mode: sd2_slave = 0, sd4_slave = 1, sd5_slave = 1 Figure 15: DCDC Step Down SD1/SD2 & SD3/SD4/SD5 Operating VSUP VSUP VSUP_SD1 2. 2uF SD1 0.6 – 3.3V 1.4 – 2A LX_SD1 1uH 10uF 10 uF FB_SD1 PVSS_SD1 2.2uF VSUP_SD3 DCDC DCDC Step Down 1 Step Down 3 1uH FB_SD3 10uF PVSS_ SD3 VSUP 22uF VSUP VSUP_SD4 VSUP_SD2 2.2uF SD 3 0.6 – 3.3V 2.1 – 3A LX_SD3 LX_SD2 FB_SD2 PVSS_SD2 DCDC DCDC Step Down 2 Step Down 4 LX_SD4 2.2uF FB_SD4 PVSS_ SD4 VSUP 1 x 2A 1 x 3A VSUP_SD5 DCDC Step Down 5 LX_SD5 FB_SD5 2.2uF PVSS_ SD5 SD1/SD2 & SD3/SD4/SD5 Operating Mode: sd2_slave = 1, sd4_slave = 1, sd5_slave = 1 AS3709 – 14 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s Parameters Figure 16: Step Down DCDC Converter Electrical Characteristics Symbol VIN Parameter Input Voltage VOUT Regulated Output Voltage VOUT_TOL Output Voltage Tolerance Conditions Pin VSUP min. 40mV Min Typ Max Unit 2.7 5.5 V 0.6125 3.35 V -3 +3 % ILIMIT Current Limit 1.2 RPMOS P-switch ON resistance 0.25 0.5 Ω RNMOS N-switch ON resistance 0.25 0.5 Ω fSW ILOAD ISUP_DCDC tMIN_ON ηEFF Switching Frequency A sdX_frequ = 1 sdX_fsel = 1 fclk_int = 4MHz 4 MHz sdX_frequ = 1 sdX_fsel = 0 fclk_int = 4MHz 3 MHz sdX_frequ = 0 sdX_fsel = 0 fclk_int = 4MHz 2 MHz VOUT ≤ 1.8V 0 1 VOUT > 1.8V 0 0.7 Load Current Current Consumption A Operating Current without Load 60 Shutdown Current 0.1 μA Minimum ON Time Efficiency 40 ns See figures below % Figure 17: Step Down DCDC External Components Symbol Parameter Conditions CFB_SDx Output Capacitor Ceramic X5R or X7R CVSUP_SDx Input Capacitor Ceramic X5R or X7R ams Datasheet, Confidential: 2013-Aug [1-02] Min Typ Max Unit 8 10 μF 2.2 μF AS3709 – 15 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Symbol LSDx Parameter Conditions Inductor Min Typ 4MHz operation 1 3MHz operation 1 2MHz operation 2.2 Max Unit μH Figure 18: DCDC SD1 Efficiency vs. Output Current 95 95 90 90 85 85 80 80 Efficiency (%) 100 Efficiency (%) 100 75 70 65 60 Vout = 1.0V Vout = 1.0V, low noise 55 40 0,001 Vout = 3.0V 0,1 1 60 Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V 45 Vout = 3.0V, low noise 0,01 65 50 Vout = 1.8V, low noise 45 70 55 Vout = 1.8V 50 75 Vout = 2.5V, low noise 40 0,001 10 0,01 Output Current (A) 0,1 1 10 Output Current (A) SD1 Efficiency vs. Output Current: VIN = 3.7V, 3MHz operation, XFL4020 1uH coil, TA = +25°C 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 19: DCDC SD1 Efficiency vs. Output Current 75 70 65 60 55 40 0,001 Vout = 1.8V 0,1 Output Current (A) 1 60 Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V 45 Vout = 1.8V, low noise 0,01 65 50 Vout = 1.0V, low noise 45 70 55 Vout = 1.0V 50 75 10 Vout = 2.5V, low noise 40 0,001 0,01 0,1 1 10 Output Current (A) SD1 Efficiency vs. Output Current: VIN = 3.0V, 3MHz operation, XFL4020 1μH coil, TA = +25°C AS3709 – 16 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 20: DCDC SD1 Efficiency vs. Output Current 75 70 65 60 1uH XFL4020, 11mΩ, 1.2V 55 50 45 40 0,001 0,01 75 70 65 60 1uH XFL4020, 11mΩ, 2.5V 1uH XFL4020, 11mΩ, LN, 1.2V 55 1uH XFL4020, 11mΩ, LN, 2.5V 1uH LQM2HP_G0, 55mΩ, 1.2V 50 1uH LQM2HP_G0, 55mΩ, 2.5V 1uH LQM2HP_G0, 55mΩ, LN, 1.2V 45 1uH LQM2HP_G0, 55mΩ, LN, 2.5V 0,1 40 0,001 1 0,01 Output Current (A) 0,1 1 Output Current (A) SD1 Efficiency vs. Output Current: VIN = 3.7V, VOUT = 1.2V/2.5V, 3MHz operation, TA = +25°C 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 21: DCDC SD1 + SD2 Efficiency vs. Output Current 75 70 65 60 Vout = 1.0V Vout = 1.0V, low noise 55 40 0,001 Vout = 3.0V 0,1 1 Output Current (A) 60 Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V 45 Vout = 3.0V, low noise 0,01 65 50 Vout = 1.8V, low noise 45 70 55 Vout = 1.8V 50 75 10 40 0,001 Vout = 2.5V, low noise 0,01 0,1 1 10 Output Current (A) SD1 + SD2 Efficiency vs. Output Current: VIN = 3.7V, 3MHz operation, XFL4020 1μH coil, TA = +25°C ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 17 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 22: DCDC SD1 + SD2 Efficiency vs. Output Current 75 70 65 75 70 65 60 Vout = 1.0V 55 Vout = 1.0V, low noise 55 50 Vout = 1.8V 50 45 Vout = 1.8V, low noise 45 40 0,001 0,01 0,1 1 10 60 Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V Vout = 2.5V, low noise 40 0,001 0,01 Output Current (A) 0,1 1 10 Output Current (A) SD1 + SD2 Efficiency vs. Output Current: VIN = 3.0V, 3MHz operation, XFL4020 1μH coil, TA = +25°C Figure 23: DCDC SD1 + SD2 Efficiency vs. Output Current SD1 + SD2 Efficiency vs. Output Current: VIN = 3.7V, VOUT = 1.2V, 3MHz operation, TA = +25°C 100 95 90 Efficiency (%) 85 80 75 70 65 60 1uH XFL4020 1uH XFL4020, low noise 55 0.6uH XAL4020 50 0.6uH XAL4020, low noise 1uH LQM2HP_G0 45 40 0,001 1uH LQM2HP_G0, low noise 0,01 0,1 1 10 Output Current (A) AS3709 – 18 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 24: DCDC SD3 + SD4 + SD5 Efficiency vs. Output Current 75 70 65 60 Vout = 1.0V Vout = 1.0V, low noise 55 40 0,001 Vout = 3.0V 0,1 1 60 Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V 45 Vout = 3.0V, low noise 0,01 65 50 Vout = 1.8V, low noise 45 70 55 Vout = 1.8V 50 75 40 0,001 10 Vout = 2.5V, low noise 0,01 Output Current (A) 0,1 1 10 Output Current (A) SD3 + SD4 + SD5 Efficiency vs. Output Current: VIN = 3.7V, 3MHz operation, XFL4020 1μH coil, TA = +25°C 100 100 95 95 90 90 85 85 80 80 Efficiency (%) Efficiency (%) Figure 25: DCDC SD3 + SD4 + SD5 Efficiency vs. Output Current 75 70 65 60 55 40 0,001 Vout = 1.8V 0,1 60 1 Output Current (A) Vout = 1.2V Vout = 1.2V, low noise Vout = 2.5V 45 Vout = 1.8V, low noise 0,01 65 50 Vout = 1.0V, low noise 45 70 55 Vout = 1.0V 50 75 10 40 0,001 Vout = 2.5V, low noise 0,01 0,1 1 10 Output Current (A) SD3 + SD4 + SD5 Efficiency vs. Output Current: VIN = 3.0V, 3MHz operation, XFL4020 1μH coil, TA = +25°C ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 19 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Figure 26: DCDC SD3 + SD4 + SD5 Efficiency vs. Output Current SD3 + SD4 + SD5 Efficiency vs. Output Current: VIN = 3.7V, VOUT = 1.2V, 3MHz operation, TA = +25°C 100 95 90 Efficiency (%) 85 80 75 70 65 60 55 1uH XFL4020, 11mΩ 50 1uH XFL4020, LN, 11mΩ 0.6uH XAL4020, 9mΩ 45 40 0,001 0.6uH XAL4020, LN, 9mΩ 0,01 0,1 1 10 Output Current (A) Figure 27: DCDC SD3 + SD4 + SD5 Efficiency vs. Output Current SD3 + SD4 + SD5 Efficiency vs. Output Current: VIN = 3.7V, VOUT = 1.2V, XFL4020 1μH coil, TA = +25°C 100 95 90 Efficiency (%) 85 80 75 70 65 60 2MHz 55 3MHz 50 4MHz 45 40 0,001 0,01 0,1 1 10 Output Current (A) AS3709 – 20 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s Universal IO LDO Regulators 2 universal IO range LDOs offer a wide input (1.8V to 5.5V) as well as a wide output (0.8 to 3.3V) voltage range to be used for general purpose peripheral supply. Up to 300mA possible output currents are offered with good noise and regulation performance and very low quiescent current even suitable for stand-by power supply. Figure 28: Universal IO LDO Block Diagram AS3709 LDO: Shows the detailed Universal IO LDO Block Diagram VIN_LDOx Error Amplifier Vref - 2.2uF + PMOS Power Device LDOx 2.2uF VSS_LDOx ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 21 D e t a i l e d D e s c r i p t i o n - Po we r M a n a g e m e n t Fu n c t i o n s Parameter Figure 29: Universal IO LDO Electrical Characteristics Symbol VIN Parameter Note Min Input Voltage Range Pin VIN_LDOx Output Voltage Tolerance Min. 40mV VOUT Output Voltage Range Pin LDOx IOUT < 150mA, 25mV steps IOUT_L Output current (Note:) VOUT_TOL Typ Max Unit 1.75 5.5 V -3 +3 % 0.825 3.3 V 0 150 mA ldoX_ilimit = 0 (150mA) ILIMIT_L Current limit (Note:) IOUT_H Output current (Note:) ILIMIT_H Current limit (Note:) 300 0 mA 300 mA ldoX_ilimit = 1 (300mA) RON On resistance PSRR Power supply rejection ratio LDO1, LDO2 f=1kHz 60 f=100kHz 30 Shut down current IQ Quiescent Current Without load Startup time Low current used during start-up Line Regulation Ω 30 Transient; Slope: tr=15μs; delta 1V Static VLDR 0.6 100 Static VLNR mA dB IOFF tSTART 500 nA 43 μA 500 us 0.07 %/V 20 mV 0.014 %/m A 30 mV Load Regulation Transient; Slope: tr=15μs; 1mA -> 300mA Note: Guaranteed by design and verified by laboratory evaluation and characterization; not production tested AS3709 – 22 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - Po w e r M a n a g e m e n t Fu n c t i o n s Figure 30: Universal IO LDO Electrical Characteristics Symbol Parameter Note Min Typ Max Unit COUT_LDOx Output Capacitor Ceramic X5R or X7R 0.7 2.2 μF CVIN_LDOx Input Capacitor Ceramic X5R or X7R 1 2.2 μF Low Power LDO V2_5 Regulator The low power LDO V2_5 is needed to supply the chip core (analog and digital) of the device. It is designed to get the lowest possible power consumption and still offering reasonable characteristics. To ensure high PSRR and stability, a low-ESR ceramic capacitor of min. 0.7μF must be connected to the output. Parameter Figure 31: Low Power V2_5 LDO Electrical Characteristics Symbol Parameter Supply Voltage Range VOUT Output Voltage RON On resistance IOFF Shut down current IQ Quiescent Current tSTART Note Min Typ Max Unit 2.4 2.5 2.6 V See VSUP Guaranteed by design Guaranteed by design, consider chip internal load for measurements Startup time 50 Ω 100 nA 3 μA 200 μs Figure 32: Universal IO LDO Electrical Characteristics Symbol CV2_5 Parameter Output Capacitor ams Datasheet, Confidential: 2013-Aug [1-02] Note Ceramic X5R or X7R Min Typ 0.7 1 Max Unit μF AS3709 – 23 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Detailed Description System Functions Start-up Normal Start-up During a normal reset cycle (e.g. after the battery is inserted), after V2_5 is above V POR and VSUP is above ResVoltRise a normal startup happens: • Configuration of DCDCs (combined mode or separated) is read from the Boot-OTP • Startup State machine reads out the internal Boot-OTP • Reset-Timer is set by the Boot-OTP • The reset is released when the Reset Timer expires (external pin XRES) Parameter Figure 33: ON Input Start-up Condition Symbol Parameter Note Min VON_IL ON Low Level Voltage VON_IH ON High Level Voltage 1.4 ION_PD ON Pull Down Current 4 AS3709 – 24 Typ Max Unit 0.4 V V 12 μA ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s Figure 34: Start-up Flowchart Start-Up VSUP connected 1. V2_5 power up 2. Readout ROM fuse VSUP debounce state N auto_off = 1 Measuring VSUP Quiesent current ~200uA N Y auto_off = 1 or power_off_at_vsuplow = 1 Y N POWER OFF state V2_5 power up Quiescent current < 10uA N VSUP > ResVoltRise for more than 5ms Y Y on_input = 1 on_input = 1 Pin ON debounce time=20msec N N Y VSUP < ResVoltFall for more than 500ms N Y Y OFF delay N power_off = 1 Die temp > 110°C (tco_110_a = 1) wait off_delay RUN startup sequence regulator startup sequence GPIO programming during sequence startup delay programmable Y Reset all Registers Switch off Regulators RESET Timer reset registers and reload fuses expect: pwr_off_at_vsuplow regulator startup executed waiting time to release XRES pin 2..160ms N Y any state Die temp > 140°C (tco_140_a = 1) ACTIVE state XRES = 1 Y Y power_off = 1 or force_reset = 1 or XRES is low or VSUP < ResVoltFall or tco_140_a = 1 or ON long-press N N force_reset = 1 or (XRES is low if stdby_reset_disable = 0) or VSUP < ResVoltFall or tco_140_a = 1 N STAND-BY state N V2_5 power up all regulators with sdX_stby_on = 1 or ldoX_stby_on = 1 enabled any interrupt applied or on_input = 1 ams Datasheet, Confidential: 2013-Aug [1-02] OFF delay wait off_delay Y standby_mode_on = 1 or GPIOx = 1 if gpiox_iosf = 6 remove stand-by force off of all regulators AS3709 – 25 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Reset XRES is a low active bi-directional pin. An external pull-up to the periphery supply has to be added. During each reset cycle the following states are controlled by the AS3709: • Pin XRES is forced to GND • Normal startup with programmable power-on sequence and regulator voltages • Reset is active until the programmable reset timer (set by register bits res_timer<2:0>) expires • All registers are set to their default values after power-on, except the reset control- and status-registers RESET Reasons Reset can be activated from 7 different sources: • V POR has been reached (VSUP reached POR level) • ResVoltFall was reached (VSUP drops below ResVoltFall) • Software forced reset • Power off mode • External triggered through the pin XRES • Over-temperature • ON-key long press Voltage Detection There are two types of voltage dependent resets: V POR and V XRES. VPOR monitors the voltage on V2_5 and V XRES monitors the voltage on VSUP. The linear regulator for V2_5 is always on and uses the voltage VSUP as its source. The pin XRES is only released if V2_5 is above VPOR and VSUP is above ResVoltRise. Power OFF To put the chip into ultralow power mode, write ‘1’ into power_off. The chip stays in power off mode until • The external pin ON is pulled high • The V POR level is touched to start a complete reset cycle The bit power_off is automatically cleared by this reset cycle. During power_off state all circuits are shut-off except the Low Power LDO (V2_5). Thus the current consumption of AS3709 is reduced to less than 7μA. The digital part is supplied by V2_5, all other circuits are turned off in this mode, including references and oscillator. Except the reset control registers, all other registers are set to their default value after power-on. AS3709 – 26 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s Software Forced Reset Writing ‘1’ into the register bit force_reset immediately starts a reset cycle. The bit force_reset is automatically cleared by this reset. External Triggered Reset If the pin XRES is pulled from high to low by an external source (e.g. microprocessor or button) a reset cycle is started as well. Over-temperature Reset The reset cycle can be started by over-temperature conditions. Long ON-key Press When applying a high level on the ON input pin for 4s/8s (depending on on_reset_delay) a reset is initiated. This is thought as a safety feature when the SW hangs up. Parameter Figure 35: XRES Input Characteristics Symbol Parameter VXRES_IL RESET Low Level Voltage VXRES_IH RESET High Level Voltage Note Min Typ Max Unit 0.4 V 1.4 V Figure 36: RESET Levels Symbol Parameter Note Min Typ Max Uni t 1.5 2.0 2.3 V Overall Power On Reset Monitor voltage on V2_5 power on reset for all internal functions VRES_RISE RESET Level for VSUP rising Monitor voltage on VSUP rising level ResVoltRise (1) V Monitor voltage on VSUP falling level 2.7 V VRES_FALL RESET Level for VSUP falling if SupResEn = 1 only ResVoltFall (2) V VPOR ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 27 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Symbol Parameter Mask time for VXRES_fall VRES_MAS K Duration for VSUP < ResVoltFall until a reset cycle is started (3) Note Min Typ Max Uni t FastResEn = 0 3 ms FastResEn = 1 4 μs Note(s) and/or Footnote(s): 1. The selection of the range and level is done via OTP. It’s recommended to set the ResVoltRise level 200mV above the ResVoltFall level to have a hysteresis. 2. 2.7V is the default value, other levels can be set via SW. 3. XRES signal is debounced with the specified mask time for rising- and falling slope of VSUP 4. VRES_FALL is only accepted if the reset condition is longer than VRES_MASK. This guard time is used to avoid a complete reset of the system in case of short drops of VSUP. Figure 37: ResVoltRise/ResVoltFall Levels Mode 000 001 010 011 100 101 110 111 3.3V 2.7V 2.8V 2.9V 3.0V 3.1V 3.2V 3.3V 3.4V 5.0V 3.6V 3.7V 3.8V 3.9V 4.0V 4.1V 4.2V 4.4V Note: If bit reslevel_5V is “1”, then the 5.0V mode is selected. AS3709 – 28 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s Stand-by Stand-by allows shutting down a part or the complete system. Stand-by can be terminated by every possible interrupt or GPIO of the PMU. The interrupt has to be enabled and GPIO has to be configured before going to stand-by. Figure 38: Stand-by State Description Enter via GPIO To enter stand-by mode the following settings have to be done: • Enable just these IRQ sources which should lead to leave stand-by mode. • Make sure that IRQ is inactive (IRQ flags get cleared by register reading) • Set the GPIO to input (gpioX_mode = 0) • Set the GPIO for stand-by control (gpioX_iosf = 6) • Set regX_select to define the sequence for going into stand-by for up to 3 regulators • Set regX_voltage_stby if another voltage is needing during stand-by • Define which regulators should be kept powered during stand-by (sdX_stby_on and ldoX_stby_on) • Activate the selected GPIO Enter via SW To enter stand-by mode the following settings have to be done: • Enable just these IRQ sources which should lead to leave stand-by mode. • Make sure that IRQ is inactive (IRQ flags get cleared by register reading) • Define which regulators should be kept powered during stand-by (sdX_stby_on and ldoX_stby_on) • Set the delay for going into stand-by after the SW command (off_delay) • Set standby_mode_on to 1 Stand-by Leave V2_5 chip supply is kept ON All other regulators are switched OFF dependent on the bits sdX_stby_on and ldoX_stby_on XRES goes active (can be disabled with standby_reset_disable) and pwr_good goes inactive The chip will come out of stand-by with • IRQ activation or • GPIO control (if entered via GPIO) Start-Up sequence is provided defined by the boot ROM. Internal References Low Power Mode Use bit low_power_on to activate the Low Power Mode. In this mode the on-chip voltage reference and the temperature supervision comparators are operating in pulsed mode. This reduces the quiescent current of the AS3709 by 45μA (typ.). Because of the pulsed function some specifications are not fulfilled in this mode (e.g. increased noise), but still the full functionality is available. Note(s): Low power mode can be controlled by the serial interface. ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 29 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Figure 39: Reference Parameter Symbol Parameter Note Min Typ Max Unit fCLK Accuracy of Internal reference clock Adjustable by serial interface register clk_int -12 fCLK +12 % GPIO Pins The device contains 2 GPIO pins. Each of the pins can be configured as digital input, digital input (with pull-up or pull-down), push-pull output or open drain output (with or without pull-up). When configured as output the output source can be a register bit, or the PWM generator. The polarity of the input and output signals can be inverted with the corresponding gpioX_invert bit, all further descriptions refer to normal (non-inverted) mode. Figure 40: GPIO Block Diagram gpioX_out: 0 Interrupt output: 1 VSUP_low output: 2 Pwr_good output: 7 Q32k output: 8 n/a: 10 n/a: 11 n/a: 13 VSUP =1 gpioX_iosf gpioX_mode = 1 & 300k gpioX_invert gpioX_in: 0 GPIO Interrupt input: 3 n/a: 4 vselect input: 5 Stand-by + vselect input: 6 n/a: 7 n/a: 12 n/a: 13 n/a: 15 gpioX_mode = 4 or 6 =1 & gpioX_mode = 0, 2, 4, 5 or 6 GPIOx gpioX_iosf 300k gpioX_mode = 1, 2 or 6 & gpioX_mode = 5 GPIO block diagram: Shows the internal structure of the IO pads AS3709 – 30 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s Figure 41: GPIO Pin Characteristics Symbol Parameter Note VGPIO_max Max. voltage on GPIO1/2 pins Pin VSUP is used as supply for the GPIO pins VOL Low level output voltage IOL=+1mA digital output VOH High level output voltage IOH=–1mA; digital push-pull output VIL Low level input voltage Digital input VIH High level input voltage Digital input ILEAKAGE Leakage current High impedance Rpull-up Pull-up resistance if enabled; VSUP = 3.6V 300 kΩ Pull-down resistance if enabled; VSUP = 3.6V 300 kΩ Rpull-down Min Typ Max Unit VSUP + 0.3 V +0.4 V 0.8*VSUP V 0.4 1.4 V V 10 μA GPIO Pins: Shows the key electrical parameter of the GPIO pins. VSUP=2.7 to 5.5V; unless otherwise mentioned. IO Functions Normal IO Operation: If set to input, the logic level of the signal present at the GPIOx pin can be read from gpioX_in. If the output mode is chosen, gpioX_out specifies the logic level of the GPIOx pin. This mode is also used for the on/off control of the DCDC and LDOs. The selection which regulator is controlled by which GPIO, is done with the gpio_ctrl_sdX or gpio_ctrl_ldoX bits. The gpioX_mode should be set to input. Interrupt Output GPIOx pin logic state is derived from the interrupt signal XINT. Whenever an interrupt is present the GPIOx pin will be pulled high. The gpioX_mode should be set to output. VSUP_low Output GPIOx pin will go high if VSUP falls below ResVoltFall and SupResEn = 0. The gpioX_mode should be set to output. GPIO Interrupt Input A falling or rising edge will set the gpio_int bit. The gpioX_mode should be set to input. ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 31 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Vselect Input As long as the GPIOx pin is high the DCDC/LDOs operate with the normal register settings. If the GPIOx pin goes low the settings will change to the ones stored in regX_voltage. The gpioX_mode should be set to input. Figure 42: GPIO Vselect Modes gpio1_iosf gpio2_iosf Vselect mode <> 5 <> 5 <> 5 5 GPIO2 controls regulator selected by reg1_select and reg2_select 5 <> 5 GPIO1 controls regulator selected by reg1_select and reg2_select 5 5 No voltage select by GPIO for regulator GPIO1 controls regulator selected by reg1_select GPIO2 controls regulator selected by reg2_select IO Functions: Shows the 4 different Vselect modes, depending on the setting of gpioX_iosf Stand-by and Vselect Input This mode is very similar to the Vselect mode described in the previous paragraph. In addition to switch between 2 register settings of 2 regulators the chip is set into stand-by mode when the GPIOx pin goes low and wakes up again when the pin is pulled high. The gpioX_mode should be set to input. GPIO1 and GPIO2 may be used to control two regulators separately. Figure 43: Stand-by and Vselect Modes gpio1_iosf gpio2_iosf <> 6 <> 6 <> 6 Vselect Mode Stand-by Control no voltage select by GPIO for regulator No 6 GPIO2 controls regulator selected by reg1_select and reg2_select Yes 6 <> 6 GPIO1 controls regulator selected by reg1_select and reg2_select Yes 6 6 GPIO1 controls regulator selected by reg1_select GPIO2 controls regulator selected by reg2_select Yes IO Functions: Shows the 4 different Vselect and Stand-by control modes, depending on the setting of gpioX_iosf AS3709 – 32 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s PWRGOOD Output This signal will go high at the end of the start-up sequence. This can be used as a second reset signal to the processor to e.g. start oscillators. The gpioX_mode should be set to output. Supervisor All Step-Down DCDCs have an integrated over-current protection. An over-temperature protection of the chip is also integrated which can be switched on with the serial interface signal temp_pmc_on (enabled by default; it is not recommended to disable the over-temperature protection). Temperature Supervision The chip has two signals for the serial interface: ov_temp_110 and ov_temp_140. The flag ov_temp_110 is automatically reset if the overtemperature condition is removed, whereas ov_temp_140 has to be reset by the serial interface with the signal rst_ov_temp_140. If the flag ov_temp_140 is set, an automatic reset of the complete chip is initiated. The chip will only start-up when the temperature falls below the T110 level (including hysteresis). The flag ov_temp_140 is not affected by this reset cycle allowing the software to detect the reason for this unexpected shutdown. Figure 44: Over-Temperature Protection Symbol Parameter Min Typ Max Unit T110 ov_temp_110 rising threshold 95 110 125 °C T140 ov_temp_140 rising threshold 125 140 155 °C THYST ov_temp_110 and ov_temp_140 hysteresis ams Datasheet, Confidential: 2013-Aug [1-02] 5 °C AS3709 – 33 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s Interrupt Generation The interrupt controller generates an interrupt request for the host controller as soon as one or more of the bits in the Interrupt 1…2 register are set by pulling low pin XINT (XINT has to be selected as a GPIO output function). All the interrupt sources can be enabled in the Interrupt Mask 1…2 register. The Interrupt 1…2 registers are cleared automatically after the host controller has read them. To prevent the AS3709 device from losing an interrupt event, the register that is read is captured before it is transmitted to the host controller via the serial interface. As soon as the transmission of the captured value is complete a logical AND operation with the bit wise inverted captured value is applied to the register to clear all interrupt bits that have already been transmitted. Clearing the read interrupt bits takes 2 clock cycles, a read access to the same register before the clearing process has completed will yield a value of ‘0’. Note that an interrupt that has been present at the previous read access will be cleared as well in case it occurs again before the clearing process has completed. During a read access to one of the interrupt registers, the GPIO pin (GPIO output function) will be released. As soon as the transferred bits of the interrupt register have been cleared the GPIO pin (GPIO output function) will be pulled low in case a new interrupt has occurred in the meantime. By doing so, the interrupt controller will work correctly with host controllers that are edge- and level-sensitive on their interrupt request input. Multiple byte read access is recommended to avoid reading the Interrupt 1 register over and over again in response to a new interrupt that has occurred in the same register (and thus pulling low the GPIO pin) before the Interrupt 2 register has been read. 2-Wire-Serial Control Interface Feature List • Fast-mode capability (max. SCL-frequency is 400 kHz) • 7+1-bit addressing mode • 60h x 8-bit data registers (word address 0x00 - 0x60) • Write formats: Single-Byte-Write, Page-Write • Read formats: Current-Address-Read, Random-Read, Sequential-Read • SDA input delay and SCL spike filtering by integrated RC-components AS3709 – 34 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s I²C Protocol Figure 45: 2-Wire Serial Symbol Definition Symbol Definition RW Note S Start condition after Stop R 1 bit Sr Repeated Start R 1 bit DW Device address for Write R 1000 0010b (80h) DR Device address for Read R 1000 0011b (81h) WA Word address R 8 bit A Acknowledge W 1 bit N No Acknowledge R 1 bit reg_data Register data/write R 8 bit data (n) Register data/read W 8 bit Stop condition R 1 bit Increment word address internally R During acknowledge P WA++ AS3709 (= slave) receive data AS3709 (= slave) transmits data ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 35 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s I²C Write Access Byte Write and Page Write formats are used to write data to the slave. Figure 46: I²C Byte Write S DW A WA A reg_data A P write register WA++ Figure 47: I²C Page Write S DW A WA A reg_data 1 A reg_data 2 write register WA++ A write register WA++ ... reg_data n A P write register WA++ The transmission begins with the START condition, which is generated by the master when the bus is in IDLE state (the bus is free). The device-write address is followed by the word address. After the word address any number of data bytes can be sent to the slave. The word address is incremented internally, in order to write subsequent data bytes on subsequent address locations. For reading data from the slave device, the master has to change the transfer direction. This can be done either with a repeated START condition followed by the device-read address, or simply with a new transmission START followed by the device-read address, when the bus is in IDLE state. The device-read address is always followed by the 1 st register byte transmitted from the slave. In Read Mode any number of subsequent register bytes can be read from the slave. The word address is incremented internally. AS3709 – 36 ams Datasheet, Confidential: 2013-Aug [1-02] D e t a i l e d D e s c r i p t i o n - S y s t e m Fu n c t i o n s I²C Read Access Random, Sequential and Current Address Read are used to read data from the slave. Figure 48: I²C Random Read S DW A WA A Sr DR A data N P read register WA++ Random Read and Sequential Read are combined formats. The repeated START condition is used to change the direction after the data transfer from the master. The word address transfer is initiated with a START condition issued by the master while the bus is idle. The START condition is followed by the device-write address and the word address. In order to change the data direction a repeated START condition is issued on the 1st SCL pulse after the acknowledge bit of the word address transfer. After the reception of the device-read address, the slave becomes the transmitter. In this state the slave transmits register data located by the previous received word address vector. The master responds to the data byte with a not-acknowledge, and issues a STOP condition on the bus. Figure 49: I²C Sequential Read S DW A WA A Sr DR A data read register WA++ A reg_data 2 read register WA++ A ... reg_data n N P read register WA++ Sequential Read is the extended form of Random Read, as more than one register-data bytes are transferred subsequently. In difference to the Random Read, for a sequential read the transferred register-data bytes are responded by an acknowledge from the master. The number of data bytes transferred in one sequence is unlimited (consider the behavior ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 37 D e t a i l e d D e s c r i p t i o n - S ys t e m Fu n c t i o n s of the word-address counter). To terminate the transmission the master has to send a not-acknowledge following the last data byte and generate the STOP condition subsequently. Figure 50: I²C Current Address Read S DR A data read register WA++ A reg_data 2 read register WA++ A ... reg_data n N P read register WA++ To keep the access time as small as possible, this format allows a read access without the word address transfer in advance to the data transfer. The bus is idle and the master issues a START condition followed by the Device-Read address. Analogous to Random Read, a single byte transfer is terminated with a not-acknowledge after the 1st register byte. Analogous to Sequential Read an unlimited number of data bytes can be transferred, where the data bytes has to be responded with an acknowledge from the master. For termination of the transmission the master sends a not-acknowledge following the last data byte and a subsequent STOP condition. I²C Parameter Figure 51: I²C SDA/SCL Characteristics Symbol Parameter VIL SCL,SDA Low Level input voltage VIH SCL,SDA High Level input voltage AS3709 – 38 Min 1.4 Typ Max Unit 0.4 V V ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Register Description Figure 52: Register Overview Addr Name <D7> <D6> <D5> <D4> <D3> <D2> <D1> 00h SD1Voltage sd1_frequ sd1_vsel<6:0> 01h SD2Voltage sd2_frequ sd2_vsel<6:0> 02h SD3Voltage sd3_frequ sd3_vsel<6:0> 03h SD4Voltage sd4_frequ sd4_vsel<6:0> 04h SD5Voltage sd5_frequ sd5_vsel<6:0> 05h LDO1Voltage ldo1_ilimit ldo1_vsel<6:0> 06h LDO2Voltage ldo2_ilimit ldo2_vsel<6:0> 0ch GPIO1control gpio1_invert gpio1_iosf<6:3> gpio1_mode<2:0> 0dh GPIO2control gpio2_invert gpio2_iosf<6:3> gpio2_mode<2:0> 10h SDcontrol 20h GPIOsignal_out 21h GPIOsignal_in 22h Reg1_Voltage reg1_voltage<7:0> 23h Reg2_Voltage reg2_voltage<7:0> 24h Reg_control 25h GPIOctrl_sd - ldo1_enabl e ldo2_enable sd5_enable sd4_enable sd3_enable sd2_enable sd1_enable - - - gpio2_out gpio1_out - - - gpio2_in gpio1_in reg2_select<7:4> gpio_ctrl_sd4<7:6> ams Datasheet, Confidential: 2013-Aug [1-02] <D0> gpio_ctrl_sd3<5:4> reg1_select<3:0> gpio_ctrl_sd2<3:2> gpio_ctrl_sd1<1:0> AS3709 – 39 Register Description Addr Name <D7> <D6> <D5> <D4> <D2> <D0> GPIOctrl_ldo - - 29h SD_control3 sd5_slave sd4_slave sd2_slave sd5_fsel sd5_fast sd5_low_nois e 30h SD_control1 sd4_low_nois e sd3_low_nois e sd2_low_no ise sd1_low_noi se sd4_fast sd3_fast sd2_fast sd1_fast 31h SD_control2 sd4_fsel sd3_fsel sd2_fsel sd1_fsel 32h Supply_voltage_ monitor 33h Startup_control 34h ResetTimer 35h FastResEn dvm_time<5:4> SupResEn ResVoltFall<5:3> stby_reset_dis able auto_off ReferenceContro l on_reset_del ay - clk_div2 36h ResetControl onkey_reset 37h Overtemperatur eControl tco_140_a tco_110_a 39h Reg_standby_m od1 disable_regp d ldo2_stby_on 73h RegStatus 74h InterruptMask1 LowVsup_int_ m 75h InterruptMask2 - off_delay<4:3> standby_mo de_on ovtmp_int_m onkey_int_ m power_off_ at_vsuplow res_timer<2:0> low_power_ on clk_int<3:1> on_input power_off force_reset rst_ov_temp_ 140 ov_temp_140 ov_temp_1 10 temp_pmc_ on sd5_stby_on sd4_stby_on sd3_stby_on sd2_stby_o n sd1_stby_on sd5_lv sd4_lv sd3_lv sd2_lv sd1_lv sd5_lv_int_ m sd4_lv_int_m sd3_lv_int_m sd2_lv_int_ m sd1_lv_int_ m gpio_restar t_int_m gpio_int_m temp_test<5:4> - - reslevel_5v reset_reason<6:3> ldo1_stby_ on gpio_ctrl_sd5<1:0> ResVoltRise<2:0> - AS3709 – 40 gpio_ctrl_ldo1<3:2> <D1> 26h sd_dvm_select<7:6> gpio_ctrl_ldo2<5:4> <D3> ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Addr Name <D7> <D6> <D5> <D4> <D3> <D2> <D1> <D0> 77h InterruptStatus1 LowBat_int_i ovtmp_int_i onkey_int_i sd5_lv_int_i sd4_lv_int_i sd3_lv_int_i sd2_lv_int_i sd1_lv_int_i 78h InterruptStatus2 - gpio_restar t_int_i gpio_int_i 90h ASIC_ID1 91h ASIC_ID2 ams Datasheet, Confidential: 2013-Aug [1-02] asic_id1<7:0> fab_id<7:4> revision<3:0> AS3709 – 41 Register Description Detailed Register Description Figure 53: SD1Voltage Register (Address 00h) Addr: 00h Bit Bit Name 7 sd1_frequ 6:0 sd1_vsel SD1Voltage Default 0 'b0000000 Access Bit Description RW Selects between high and low frequency dependent on sd1_fsel 0 : 2MHz if sd1_fsel=0, 3MHz if sd1_fsel=1 1 : 3MHz if sd1_fsel=0, 4MHz if sd1_fsel=1 RW The voltage select bits set the SD1 output voltage level and power the SD1 converter down. 00h : SD1 powered down 01h-40h : V_SD1=0.6V+sd1_vsel*12.5mV 41h-70h : V_SD1=1.4V+(sd1_vsel-40h)*25mV 71h-7Fh : V_SD1=2.6V+(sd1_vsel-70h)*50mV Figure 54: SD2Voltage Register (Address 01h) Addr: 01h Bit 7 6:0 AS3709 – 42 Bit Name sd2_frequ sd2_vsel SD2Voltage Default 0 'b000 0000 Access Bit Description RW Selects between high and low frequency dependent on sd2_fsel 0 : 2MHz if sd2_fsel=0, 3MHz if sd2_fsel=1 1 : 3MHz if sd2_fsel=0, 4MHz if sd2_fsel=1 RW The voltage select bits set the SD2 output voltage level and power the SD2 converter down. 00h : SD2 powered down 01h-40h : V_SD2=0.6V+sd2_vsel*12.5mV 41h-70h : V_SD2=1.4V+(sd2_vsel-40h)*25mV 71h-7Fh : V_SD2=2.6V+(sd2_vsel-70h)*50mV ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 55: SD3Voltage Register (Address 02h) Addr: 02h Bit 7 6:0 Bit Name sd3_frequ sd3_vsel SD3Voltage Default 0 'b000 0000 Access Bit Description RW Selects between high and low frequency dependent on sd3_fsel 0 : 2MHz if sd3_fsel=0, 3MHz if sd3_fsel=1 1 : 3MHz if sd3_fsel=0, 4MHz if sd3_fsel=1 RW The voltage select bits set the SD3 output voltage level and power the SD3 converter down. 00h : SD3 powered down 01h-40h : V_SD3=0.6V+sd3_vsel*12.5mV 41h-70h : V_SD3=1.4V+(sd3_vsel-40h)*25mV 71h-7Fh : V_SD3=2.6V+(sd3_vsel-70h)*50mV Figure 56: SD4Voltage Register (Address 03h) Addr: 03h Bit 7 6:0 Bit Name sd4_frequ sd4_vsel SD4Voltage Default 0 'b000 0000 ams Datasheet, Confidential: 2013-Aug [1-02] Access Bit Description RW Selects between high and low frequency dependent on sd4_fsel 0 : 2MHz if sd3_fsel=0, 3MHz if sd3_fsel=1 1 : 3MHz if sd3_fsel=0, 4MHz if sd3_fsel=1 RW The voltage select bits set the SD4 output voltage level and power the SD4 converter down. 00h : SD4 powered down 01h-40h : V_SD4=0.6V+sd4_vsel*12.5mV 41h-70h : V_SD4=1.4V+(sd4_vsel-40h)*25mV 71h-7Fh : V_SD4=2.6V+(sd4_vsel-70h)*50mV AS3709 – 43 Register Description Figure 57: SD5Voltage Register (Address 04h) Addr: 04h Bit Bit Name 7 sd5_frequ 6:0 sd5_vsel SD5Voltage Default 0 'b000 0000 Access Bit Description RW Selects between high and low frequency dependent on sd5_fsel 0 : 2MHz if sd3_fsel=0, 3MHz if sd3_fsel=1 1 : 3MHz if sd3_fsel=0, 4MHz if sd3_fsel=1 RW The voltage select bits set the SD5 output voltage level and power the SD5 converter down. 00h : SD5 powered down 01h-40h : V_SD4=0.6V+sd4_vsel*12.5mV 41h-70h : V_SD4=1.4V+(sd4_vsel-40h)*25mV 71h-7Fh : V_SD4=2.6V+(sd4_vsel-70h)*50mV Figure 58: LDO1Voltage Register (Address 05h) Addr: 05h LDO1Voltage Bit Bit Name Default Access 7 ldo1_ilimit 0 RW Sets limit of LDO1 0 : 150mA operating range 1 : 300mA operating range RW The voltage select bits set the LDO1 output voltage 0.825V...3.3V, 25mV steps 00h : LDO1 off 01h-24h : V_LDO1=0.8V+ldo1_vsel*25mV 25h-3fh : Do not use 40h-7Fh : V_LDO1=1.725V+(ldo1_vsel-40h)*25mV 6:0 ldo1_vsel 'b00 0000 Bit Description Figure 59: LDO2Voltage Register (Address 06h) Addr: 06h LDO2Voltage Bit Bit Name Default Access 7 ldo2_ilimit 0 RW Sets limit of LDO2 0 : 150mA operating range 1 : 300mA operating range RW The voltage select bits set the LDO2 output voltage 0.825V...3.3V, 25mV steps 00h : LDO2 off 01h-24h : V_LDO2=0.8V+ldo2_vsel*25mV 25h-3fh : Do not use 40h-7Fh : V_LDO2=1.725V+(ldo2_vsel-40h)*25mV 8:0 AS3709 – 44 ldo2_vsel 'b00 0000 Bit Description ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 60: GPIO1control Register (Address 0ch) Addr: 0ch GPIO1control Bit Bit Name Default Access 7 gpio1_invert 0 RW Invert GPIO1 input/output 0 : Normal mode 1 : Invert input or output RW Select the GPIO1 special function .0 : Normal I/O operation .1 : Interrupt output .2 : VSUP_low output .3 : GPIO interrupt input .4 : NA .5 : Vselect input, (apply on reg1_select and reg2_select, if gpio2_iosf =5 then apply on reg1_select only) .6 : standby + Vselect + restart interrupt input .7 : pwr_good output .8 : NA .9 : NA 10 : NA 11 : NA 12 : NA 13 : NA 14 : NA 15 : NA RW Selects the GPIO1 mode (I, I/O, Tri, Pulls) 0 : Input 1 : Output (push and pull) 2 : IO (open drain, only NMOS is active) 3 : NA 4 : Input with pullup 5 : Input with pulldown 6 : IO (open drain (NMOS) with pullup) 7 : NA 6:3 2:0 gpio1_iosf gpio1_mode 'b0000 'b011 ams Datasheet, Confidential: 2013-Aug [1-02] Bit Description AS3709 – 45 Register Description Figure 61: GPIO2control Register (Address 0dh) Addr: 0dh GPIO2control Bit Bit Name Default Access 7 gpio2_invert 0 RW Invert GPIO2 input/output 0 : Normal mode 1 : Invert input or output RW Select the GPIO2 special function .0 : Normal i/o operation .1 : Interrupt output .2 : VSUP_low output .3 : GPIO interrupt input .4 : NA .5 : Vselect input, (apply on reg1_select and reg2_select, if gpio1_iosf=5 then apply on reg2_select only) .6 : standby + Vselect + restart interrupt input .7 : pwr_good output .8 : NA .9 : NA 10 : NA 11 : NA 12 : NA 13 : NA 14 : NA 15 : NA RW Selects the GPIO2 mode (I, I/O, Tri, Pulls) 0 : Input 1 : Output (push and pull) 2 : IO (open drain, only NMOS is active) 3 : NA 4 : Input with pullup 5 : Input with pulldown 6 : IO (open drain (NMOS) with pullup) 7 : NA 6:3 2:0 AS3709 – 46 gpio2_iosf gpio2_mode 'b0000 'b011 Bit Description ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 62: SDcontrol Register (Address 10h) Addr: 10h SDcontrol Bit Bit Name Default Access Bit Description 7 - 'b0 N/A Do not use 6 ldo2_enable 'b1 RW Global LDO2 enable 0 : LDO2 off 1 : LDO2 on 5 ldo1_enable 'b1 RW Global LDO1 enable 0 : LDO1 off 1 : LDO1 on 4 sd5_enable 'b1 RW Global stepdown5 enable 0 : SD off 1 : SD on 3 sd4_enable 'b1 RW Global stepdown4 enable 0 : SD off 1 : SD on 2 sd3_enable 'b1 RW Global stepdown3 enable 0 : SD off 1 : SD on 1 sd2_enable 'b1 RW Global stepdown2 enable 0 : SD off 1 : SD on 0 sd1_enable 'b1 RW Global stepdown1 enable 0 : SD off 1 : SD on Figure 63: GPIOsignal_out Register (Address 20h) Addr: 20h GPIOsignal_out Bit Bit Name Default Access 7:2 - 'b0000 N/A Do not use 1 gpio2_out 0 RW This bit determines the output signal of the GPIO2 pin when selected as output source. 0 gpio1_out 0 RW This bit determines the output signal of the GPIO1 pin when selected as output source. ams Datasheet, Confidential: 2013-Aug [1-02] Bit Description AS3709 – 47 Register Description Figure 64: GPIOsignal_in Register (Address 21h) Addr: 21h GPIOsignal_in Bit Bit Name Default Access Bit Description 7:2 - 'b0000 N/A Do not use 1 gpio2_in 0 RO This bit reflects the logic level of the GPIO2 pin when configured as digital input pin. 0 gpio1_in 0 RO This bit reflects the logic level of the GPIO1 pin when configured as digital input pin. Figure 65: Reg1_Voltage Register (Address 22h) Addr: 22h Bit 7:0 Bit Name reg1_voltage Reg1_Voltage Default 'b0000 0000 Access RW Bit Description This register is mapped to the register address 0h+Reg1_select , if gioX_iosf = 5 or 6 (Vselect input), and input = 1. This feature allows voltage switching of a predefined regulator with just one GPIO input. 0 ..FFh : Selects voltage and frequency bits of DCDC Figure 66: Reg2_Voltage Register (Address 23h) Addr: 23h Bit 7:0 Bit Name reg2_voltage AS3709 – 48 Reg2_Voltage Default 'b0000 0000 Access RW Bit Description This register is mapped to the register address 0h+Reg1_select, if gioX_iosf=5 or 6 (Vselect input), and input = 1, This feature allows voltage switching of a predefined regulator with just one GPIO input 0 ..FFh : Selects voltage and frequency bits of DCDC ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 67: Reg_control Register (Address 24h) Addr: 24h Reg_control Bit Bit Name Default Access Bit Description 7:4 reg2_select 'b1111 RW Selects regulator for mapping feature; if reg_select2 ≥ 0Ch, then feature is disabled. 3:0 reg1_select 'b1111 RW Selects regulator for mapping feature; if reg_select1 ≥ 0Ch, then feature is disabled. Figure 68: GPIOctrl_sd Register (Address 25h) Addr: 25h Bit 7:6 5:4 3:2 1:0 Bit Name gpio_ctrl_sd4 gpio_ctrl_sd3 gpio_ctrl_sd2 gpio_ctrl_sd1 GPIOctrl_sd Default 'b00 'b00 'b00 'b00 ams Datasheet, Confidential: 2013-Aug [1-02] Access Bit Description RW Enable GPIO control of DCDC SD4. GPIO ctrl only enabled, if sd4_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA RW Enable GPIO control of DCDC SD3. GPIO ctrl only enabled, if sd3_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA RW Enable GPIO control of DCDC SD2. GPIO ctrl only enabled, if sd2_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA RW Enable GPIO control of DCDC SD1. GPIO ctrl only enabled, if sd1_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA AS3709 – 49 Register Description Figure 69: GPIOctrl_ldo Register (Address 26h) Addr: 26h GPIOctrl_ldo Bit Bit Name Default Access 7:6 - 'b00 N/A - RW Enable GPIO control of LDO2. GPIO ctrl only enabled, if ldo2_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA RW Enable GPIO control of LDO1. GPIO ctrl only enabled, if ldo1_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA RW Enable GPIO control of SD5. GPIO ctrl only enabled, if sd5_vsel > 0 0 : No GPIO control 1 : Controlled by GPIO1 2 : Controlled by GPIO2 3 : NA 5:4 3:2 gpio_ctrl_ldo2 gpio_ctrl_ldo1 1:0 AS3709 – 50 gpio_ctrl_sd5 'b00 'b00 'b00 Bit Description ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 70: SD_control3 Register (Address 29h) Addr: 29h SD_control3 Bit Bit Name Default Access 7 sd5_slave 0 RW Enables slave mode of SD5 0 : Normal mode of SD5 1 : SD5 is slave of SD3 7 sd4_slave 0 RW Enables slave mode of SD4 0 : Normal mode of SD4 1 : SD4 is slave of SD3 5 sd2_slave 0 RW Enables slave mode of SD2 0 : Normal mode of SD2 1 : SD2 is slave of SD1 4 sd5_fsel 0 RW Selects between high and low frequency range 0 : 2 or 3MHz frequency (selectable by sd5_frequ) 1 : 3 or 4MHz frequency (selectable by sd5_frequ) RW Selects a faster regulation mode for SD5 suitable for larger load changes. 0 : Normal mode, Cext=10μF 1 : Fast mode, Cext=22μF required 3 sd5_fast 0 Bit Description 2 sd5_low_noise 0 RW Enables low noise mode of SD5. If enabled smaller current pulses and output ripple is activated. 0 : Normal mode. Minimum current pulses of >100mA applied in skip mode. 1 : Low noise mode. Only minimum on time applied in skip mode. 1:0 - 'b00 N/A - ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 51 Register Description Figure 71: SD_control1 Register (Address 30h) Addr: 30h Bit 7 6 5 4 Bit Name sd4_low_noise sd3_low_noise sd2_low_noise sd1_low_noise 3 2 1 0 AS3709 – 52 sd4_fast sd3_fast sd2_fast sd1_fast SD_control1 Default 0 0 0 0 0 0 0 0 Access Bit Description RW Enables low noise mode of SD4. If enabled smaller current pulses and output ripple is activated. 0 : Normal mode. Minimum current pulses of >100mA applied in skip mode. 1 : Low noise mode. Only minimum on time applied in skip mode. RW Enables low noise mode of SD3. If enabled smaller current pulses and output ripple is activated. 0 : Normal mode. Minimum current pulses of >100mA applied in skip mode. 1 : Low noise mode. Only minimum on time applied in skip mode. RW Enables low noise mode of SD2. If enabled smaller current pulses and output ripple is activated. 0 : Normal mode. Minimum current pulses of >100mA applied in skip mode. 1 : Low noise mode. Only minimum on time applied in skip mode. RW Enables low noise mode of SD1. If enabled smaller current pulses and output ripple is activated. 0 : Normal mode. Minimum current pulses of >100mA applied in skip mode. 1 : Low noise mode. Only minimum on time applied in skip mode. RW Selects a faster regulation mode for SD4 suitable for larger load changes. 0 : Normal mode, Cext=10μF 1 : Fast mode, Cext=22μF required RW Selects a faster regulation mode for SD3 suitable for larger load changes. 0 : normal mode, Cext=10μF 1 : fast mode, Cext=22μF required RW Selects a faster regulation mode for SD2 suitable for larger load changes. 0 : Normal mode, Cext=10μF 1 : Fast mode, Cext=22μF required RW Selects a faster regulation mode for SD1 suitable for larger load changes. 0 : Normal mode, Cext=10μF 1 : Fast mode, Cext=22μF required ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 72: SD_control2 Register (Address 31h) Addr: 31h Bit 7:6 Bit Name sd_dvm_select SD_control2 Default 'b00 Access Bit Description RW Apply DVM counter to the following DCDC converter 0 : Select SD1 for DVM 1 : Select SD2 for DVM 2 : Select SD3 for DVM 3 : Select SD5 for DVM 5:4 dvm_time 'b00 RW Time steps of DVM voltage change of selected step down, if voltage of step Down is changed during operation (sdx_vsel) voltage is decreased/increased by single steps 12.5mV 0 : 0 μsec, immediate change (no DVM) 1 : 4 μsec time delay between steps 2 : 8 μsec time delay between steps 3 : 16 μsec time delay between steps 3 sd4_fsel 0 RW Selects between high and low frequency range 0 : 2 or 3MHz frequency (selectable by sd4_frequ) 1 : 3 or 4MHz frequency (selectable by sd4_frequ) 2 sd3_fsel 0 RW Selects between high and low frequency range 0 : 2 or 3MHz frequency (selectable by sd3_frequ) 1 : 3 or 4MHz frequency (selectable by sd3_frequ) 1 sd2_fsel 0 RW Selects between high and low frequency range 0 : 2 or 3MHz frequency (selectable by sd2_frequ) 1 : 3 or 4MHz frequency (selectable by sd2_frequ) 0 sd1_fsel 0 RW Selects between high and low frequency range 0 : 2 or 3MHz frequency (selectable by sd1_frequ) 1 : 3 or 4MHz frequency (selectable by sd1_frequ) ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 53 Register Description Figure 73: Supply_voltage_monitor Register (Address 32h) Addr: 32h Supply_voltage_monitor Bit Bit Name Default Access 7 FastResEn 0 RW 6 5:3 2:0 AS3709 – 54 SupResEn ResVoltFall ResVoltRise 0 'b000 'b000 Bit Description 0 : ResVoltFall debounce time = 3msec 1 : ResVoltFall debounce time = 4μsec (tbd) RW 0 : A reset is generated if VSUP falls below 2.7V ** 1 : A reset is generated if VSUP falls below ResVoltFall ** If VSUP falls below ResVoltFall only an interrupt is generated (if enabled) and the μProcessor can shut down the system RW This value determines the reset level ResVoltFall for falling VSUP. It is recommended to set this value at least 200mV lower than ResVoltRise (the levels differ between 3.3V and 5V supply) 0 : 2.7V / 3.6V 1 : 2.8V / 3.7V 2 : 2.9V / 3.8V 3 : 3.0V / 3.9V 4 : 3.1V / 4.0V 5 : 3.2V / 4.1V 6 : 3.3V / 4.2V 7 : 3.4V / 4.4V RO (OTP) This value determines the reset level ResVoltRise for rising VSUP. It is recommended to set this value at least 200mV higher than ResVoltFall (the levels differ between 3.3V and 5V supply) 0 : 2.7V / 3.6V 1 : 2.8V / 3.7V 2 : 2.9V / 3.8V 3 : 3.0V / 3.9V 4 : 3.1V / 4.0V 5 : 3.2V / 4.1V 6 : 3.3V / 4.2V 7 : 3.4V / 4.4V ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 74: Startup_Control Register (Address 33h) Addr: 33h Startup_Control Bit Bit Name Default Access 7:2 - ‘b000 0000 N/A Do not use RW Selects the 5V supply reset level (see ResVoltRise and ResVoltFall) 0 : 3.3V level 1 : 5.0V level RW Switch on Power off mode if low VSUP is detected during active or standby mode (Pin ON= low and bit auto_off=0) 0 : If low VSUP is detected, VSUP is continuously monitored and chip startup initiated if VSUP is above ResVoltRise 1 : If low VSUP is detected, enter power off mode 1 0 reslevel_5v power_off_ at_vsuplow 0 0 ams Datasheet, Confidential: 2013-Aug [1-02] Bit Description AS3709 – 55 Register Description Figure 75: ResetTimer Register (Address 34h) Addr: 34h ResetTimer Bit Bit Name Default Access 7 - 'b0 N/A Do not use RW Disable Reset output signal (pin XRES) in standby mode. 0 : Normal mode, reset is active in standby mode 1 : No reset in standby mode and during exit of stand-by mode RO Defines startup behavior at first VSUP connection 0 : Startup of chip if VSUP>ResVoltRise 1 : Enter power off mode (Startup with ON key) RW Set delay between I²C command, GPIO or Reset signal for power_off, standby mode or reset and execution of that command. 0 : No delay 1 : 8 msec 2 : 16 msec 3 : 32 msec RW Set Reset Time, after the last regulator has started 0 : RESTIME = 2ms 1 : RESTIME = 4ms 2 : RESTIME = 8ms 3 : RESTIME = 16ms 4 : RESTIME = 32ms 5 : RESTIME = 64ms 6 : RESTIME = 128ms 7 : RESTIME = 160ms 6 stby_reset_disa ble 5 4:3 2:0 AS3709 – 56 auto_off off_delay res_timer 0 0 'b01 'b000 Bit Description ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 76: ReferenceControl Register (Address 35h) Addr: 35h ReferenceControl Bit Bit Name Default Access 7 on_reset_delay 0 RW Sets the on reset delay time 0 : 8 sec (if onkey_reset=1) 1 : 4 sec (if onkey_reset=1) 6 - 0 RW - RW Divide internal clock oscillator by 2 to reduce quiescent current for low power operation 0 : Normal mode 1 : Internal clock frequency divided by two. All timings are increased by two. Switching frequency of all DCDC converters are divided by two. Reduced transient performance of DCDC converters. RW Setting to 1 sets the PMU into standby mode. All regulators are disabled except those regulators enabled by register Reg standby mode. XRES will be pulled to low. A normal startup of all regulators will be done with any interrupt (has to be enabled before entering standby mode). During this startup, regulators defined by Reg standby mode register are continuously on. RW Sets the internal CLK frequency fCLK used for fuel gauge, DCDCs, PWM, ... 0 : 4 MHz (default) 1 : 3.8 MHz 2 : 3.6 MHz 3 : 3.4 MHz 4 : 3.2 MHz 5 : 3.0 MHz 6 : 2.8 MHz 7 : 2.6 MHz All frequencies, timings and delays in this datasheet are based on 4MHz clk_int RW Enable low power mode of internal reference. 0 : Standard mode 1 : Low power mode - all specification except noise parameters are still valid. Iq reduced by approx. 30μA 5 4 3:1 0 clk_div2 standby_mode _on clk_int low_power_on 0 0 'b000 0 ams Datasheet, Confidential: 2013-Aug [1-02] Bit Description AS3709 – 57 Register Description Figure 77: ResetControl Register (Address 36h) Addr: 36h ResetControl Bit Bit Name Default Access 7 onkey_reset 0 RW Bit Description 0 : Reset after 4/8 seconds ON pressed disabled 1 : Reset after 4/8 seconds ON pressed enabled Flags to indicate to the software the reason for the last reset .0 : VPOR has been reached (VSUP connection from scratch) .1 : ResVoltFall was reached (VSUP drop below 2.75V) .2 : Software forced by force_reset .3 : Software forced by power_off and ON was pulled high .4 : Software forced by power_off and charger was detected .5 : External triggered through the pin XRES .6 : Reset caused by overtemperature T140 .7 : NA .8 : Reset caused by 4/8 seconds ON press .9 : NA 10 : NA 11 : Reset caused by interrupt in standby mode 12 : Reset caused by ON pulled high in standby mode 6:3 reset_reason 'b0000 RW 2 on_input 0 R_PUSH Read: This flag represents the state of the ON pad directly Write: Setting to 1 resets the 4/8 sec. onkey_reset timer 1 power_off 0 RW Setting to 1 starts a reset cycle, but waits after the Reg_off state for a falling edge on the pin ON 0 force_reset 0 RW Setting to 1 starts a complete reset cycle AS3709 – 58 ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 78: OvertemperatureControl Register (Address 37h) Addr: 37h OvertemperatureControl Bit Bit Name Default Access 7:4 - 'b0000 N/A Do not use 3 rst_ov_temp_1 40 RWP If the over-temperature threshold 2 has been reached, the flag ov_temp_140 is set and a reset cycle is started. ov_temp_140 should be reset by writing 1 and afterward 0 to rst_ov_temp_140. 0 Bit Description 2 ov_temp_140 0 RO Flag that the over-temperature threshold 2 (T140) has been reached - this flag is not reset by an over-temperature caused reset and has to be reset by rst_ov_temp_140. 1 ov_temp_110 0 RO Flag that the over-temperature threshold 1 (T110) has been reached 0 temp_pmc_on 1 RO Switch on / off the temperature supervision; default: on - all other bits are only valid if set to 1 leave at 1, do not disable Figure 79: Reg_standby_mod1 Register (Address 39h) Addr: 39h Bit Bit Name Reg_standby_mod1 Default Access Bit Description 7 disable_regpd 0 RW This bit disables the pulldown of all regulators 0 : Normal operation approx. 1kΩ pulldown of all regulators 1 : Pulldown disabled >100kΩ of all regulators 6 ldo2_stby_on 0 RW Enable LDO2 in standby mode 5 ldo1_stby_on 0 RW Enable LDO1 in standby mode 4 sd5_stby_on 0 RW Enable Step down 4 in standby mode 3 sd4_stby_on 0 RW Enable Step down 4 in standby mode 2 sd3_stby_on 0 RW Enable Step down 3 in standby mode 1 sd2_stby_on 0 RW Enable Step down 2 in standby mode 0 sd1_stby_on 0 RW Enable Step down 1 in standby mode ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 59 Register Description Figure 80: RegStatus Register (Address 73h) Addr: 73h RegStatus Bit Bit Name Default Access Bit Description 7:5 - ‘b000 N/A Do not use 4 sd5_lv 0 RO Bit is set when voltage of SD5 drops below low voltage threshold (-5%) (1msec debounce time default) 3 sd4_lv 0 RO Bit is set when voltage of SD4 drops below low voltage threshold (-5%) (1msec debounce time default) 2 sd3_lv 0 RO Bit is set when voltage of SD3 drops below low voltage threshold (-5%) (1msec debounce time default) 1 sd2_lv 0 RO Bit is set when voltage of SD2 drops below low voltage threshold (-5%) (1msec debounce time default) 0 sd1_lv 0 RO Bit is set when voltage of SD1 drops below low voltage threshold (-5%) (1msec debounce time default) Figure 81: InterruptMask1 Register (Address 74h) Addr: 74h InterruptMask1 Bit Bit Name Default Access 7 LowVsup_int_m 1 RW Set to 0 to enable the interrupt 6 ovtmp_int_m 1 RW Set to 0 to enable the interrupt 5 onkey_int_m 1 RW Set to 0 to enable the interrupt 4 sd5_lv_int_m 1 RW Set to 0 to enable the interrupt 3 sd4_lv_int_m 1 RW Set to 0 to enable the interrupt 2 sd3_lv_int_m 1 RW Set to 0 to enable the interrupt 1 sd2_lv_int_m 1 RW Set to 0 to enable the interrupt 0 sd1_lv_int_m 1 RW Set to 0 to enable the interrupt AS3709 – 60 Bit Description ams Datasheet, Confidential: 2013-Aug [1-02] Register Description Figure 82: InterruptMask2 Register (Address 75h) Addr: 75h InterruptMask2 Bit Bit Name Default Access Bit Description 7:2 - ‘b0000 00 N/A Do not use 1 gpio_restart_int_m 1 RW Set to 0 to enable the interrupt 0 gpio_int_m 1 RW Set to 0 to enable the interrupt Figure 83: InterruptStatus1 Register (Address 77h) Addr: 77h InterruptStatus1 Bit Bit Name Default Access Bit Description 7 LowBat_int_i 0 POP Bit is set when VSUP drops below vres_fall rising edge only 6 ovtmp_int_i 0 POP Bit is set when 110deg is exceeded rising edge only 5 onkey_int_i 0 POP Rising and falling edge 4 sd5_lv_int_i 0 POP Rising edge only 3 sd4_lv_int_i 0 POP Rising edge only 2 sd3_lv_int_i 0 POP Rising edge only 1 sd2_lv_int_i 0 POP Rising edge only 0 sd1_lv_int_i 0 POP Rising edge only Figure 84: InterruptStatus2 Register (Address 78h) Addr: 78h InterruptStatus2 Bit Bit Name Default Access 7:2 - ‘b0000 00 N/A Do not use 1 gpio_restart_int_i 0 POP Falling edge 0 gpio_int_i 0 POP Rising and falling edge ams Datasheet, Confidential: 2013-Aug [1-02] Bit Description AS3709 – 61 Register Description Figure 85: ASIC_ID1 Register (Address 90h) Addr: 90h ASIC_ID1 Bit Bit Name Default Access 7:0 ID1 ‘b10001110 RO Bit Description - Figure 86: ASIC_ID2 Register (Address 91h) Addr: 91h ASIC_ID2 Bit Bit Name Default Access 3:0 revision ‘b0010 RO AS3709 – 62 Bit Description Note: Metal fuse!!! ams Datasheet, Confidential: 2013-Aug [1-02] Application Information Application Information VSUP LDO1 V2_5 LDO2 Figure 87: Application Schematic VSUP VSUP 2.2μF 2.2μF 2.2μF 2.2μF VSUP 401-1426-1-ND KMR211GLFS 2.2μF GND ON GND GND GND GND SD1 24 25 SCLK SDA GND 26 27 VSUP 1M 29 28 GPIO1 GPIO2 XRES 23 V2_5 SCLK SDA ON XRES GPIO1 GPIO2 14 13 VSUP_SD1 LX_SD1 FB_SD1 PVSS_SD1 LDOs AS3709 uPMIC V2_5 10k VSUP_SD3 LX_SD3 FB_SD3 PVSS_SD3 GND VSUP 2.2μF 18 17 15 16 GND SD2 1μH 10μF 7 8 10 9 GND VSUP 2.2μF PVSS_SD4 FB_SD4 LX_SD4 VSUP_SD4 PVSS_SD5 FB_SD5 LX_SD5 VSUP_SD5 VSUP_SD2 LX_SD2 FB_SD2 PVSS_SD2 22 21 19 20 GND SD3 1μH 10μF 5 6 4 3 30 33 401-1426-1-ND KMR211GLFS 32 31 1 2 GNDSENSE EP_VSS 1μF GND 10μF AS3709 DCDC SD 1-5 8k2 VIN_LDO2 LDO2 8k2 Logic & Control 1M VIN_LDO1 LDO1 11 12 1μH GND GND GND Vsup Vsup 1μH 1μH 2.2μF ams Datasheet, Confidential: 2013-Aug [1-02] GND GND SD4 GND 10μF SD5 10μF 2.2μF GND AS3709 – 63 Application Information Figure 88: Layout Guidelines 1/2 COUT_SD5 SD5 L4 L5 CIN_SD4 GPIO1 GPIO2 XRES ON SDA 28 27 26 25 21 QFN 32-pin 4x4mm 6 Exposed Pad: GND 7 LX_SD2 16 15 FB_SD2 14 VIN_LDO1 13 LDO1 11 12 LDO2 VIN_LDO2 10 9 3 FB_SD1 18 COUT_SD1 17 FB_SD3 LX_SD3 PV SS _S D FB_SD1 19 33 SD1 PVSS_SD1 LX_SD2 2 D _S CIN_SD3 CIN_SD1 SS PV L3 LX_SD1 20 8 VSUP_SD3 L1 22 AS3709 4 5 PVSS_SD4 VSSA 23 3 LX_SD4 29 24 2 VSUP_SD2 FB_SD4 4 SD P_ COUT_SD4 1 SCL V2 K _5 U VS SD4 30 5 5 D _S LX SD P_ U VS FB_SD4 32 CIN_SD5 31 FB_SD5 PVSS_SD5 CIN_LDO1 FB_SD2 SD3 SD2 L2 COUT_SD2 COUT_LDO1 COUT_SD3 COUT_LDO2 FB_SD3 CIN_LDO2 CIN_SD2 FB_SD2 Layout Guidelines 1/2: This figure shows the recommended layout and placement of the external components for the 5 x 1A application circuit. Red lines and areas are connections on TOP layer. Grey lines and areas are GND and PVSS connections on TOP layer. Light blue lines and areas are connections on an inner layer or BOTTOM layer. Black round dots are vias. VSUP areas should be connected to an inner VSUP plane via vias. GND and PVSS areas should be connected to an inner GND plane via vias. A AS3709 – 64 ams Datasheet, Confidential: 2013-Aug [1-02] Application Information PCB with minimum 4 layers is recommended. Figure 89: Layout Guidelines 2/2 L3 LX_SD4 GPIO2 XRES ON SDA 27 26 25 2 23 21 QFN 32-pin 4x4mm 5 FB_SD1 13 14 LDO1 VIN_LDO1 16 12 LDO2 15 11 VIN_LDO2 9 10 VSUP_SD2 FB_SD1 D _S SS 2 PV SS _S D COUT_SD1/2 17 PV COUT_SD3/4/5 CIN_SD3 3 FB_SD3 FB_SD3 PVSS_SD1 18 33 8 LX_SD3 LX_SD1 C IN_SD1 19 7 VSUP_SD3 LX_SD1 20 Exposed Pad: GND 6 PVSS_SD4 L1 VSUP_SD1 22 AS3709 4 SCL V2 K _5 GPIO1 28 24 3 CIN_SD4 VSSA 32 1 LX_SD2 VSUP SD4+SD5 31 5 LX_SD5 29 SD CIN_SD5 30 _ SS PV COUT_SD3/4/5 CIN_SD2 COUT_SD1/2 CIN_LDO1 COUT_LDO1 COUT_LDO2 CIN_LDO2 COUT_SD3/4/5 SD1 & SD1 SD3 & SD4 & SD5 Layout Guidelines 2/2: Layout Guidelines 2/2: This figure shows the recommended layout and placement of the external components for the 1 x 2A & 1 x 3A application circuit. Red lines and areas are connections on TOP layer. Grey lines and areas are GND and PVSS connections on TOP layer. Light blue lines and areas are connections on an inner layer or BOTTOM layer. Black round dots are vias. VSUP areas should be connected to an inner VSUP plane via vias. GND and PVSS areas should be connected to an inner GND plane via vias. A PCB with minimum 4 layers is recommended. ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 65 Pack age Drawings & Mark ings Package Drawings & Markings Figure 90: QFN32 4x4 0.4mm Pitch Package Drawing REF. MIN NOM MAX A 0.80 0.90 1.00 A1 0 0.02 0.05 A3 0.20 REF L 0.35 0.40 0.45 L1 0 - 0.15 b 0.15 0.20 0.25 D 4.00 BSC E 4.00 BSC e 0.40 BSC D2 2.60 2.70 2.80 E2 2.60 2.70 2.80 aaa - 0.10 - bbb - 0.07 - ccc - 0.10 - ddd - 0.05 - eee - 0.08 - fff - 0.10 - N 32 Note(s) and/or Footnote(s): 1. Dimensioning and tolerancing conform to ASME Y14.5M-1994. 2. All dimensions are in millimeters. Angles are in degrees. 3. Dimension b applies to metallized terminal and is measured between 0.25mm and 0.30mm from terminal tip. Dimension L1 represents terminal full back from package edge up to 0.15mm is acceptable. 4. Coplanarity applies to the exposed heat slug as well as the terminal. 5. Radius on terminal is optional. 6. N is the total number of terminals. AS3709 – 66 ams Datasheet, Confidential: 2013-Aug [1-02] Pa c k a g e D r a w i n g s & M a r k i n g s Figure 91: WLP36 0.4mm Pitch Package Drawing Note(s) and/or Footnote(s): 1. Pin 1 = A1 2. ccc Coplanarity 3. A1 dimensions are in μm ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 67 Pack age Drawings & Mark ings Figure 92: QFN Marking AS3709 K2V0-xx YYWWXZZ QFN Marking: Shows the package marking of the QFN product version. Figure 93: QFN Package Code YY WW X ZZ Year Manufacturing week Plant identifier Free choice Figure 94: Start-up Revision Code Revision Code Sequence K2V0-ES Engineering samples, no sequence programmed or sequence programmed on request K2V0-00 Standard programming (no sequence programmed) K2V0-xx Customer specified sequence programmed during production test Figure 95: WL-CSP Marking AS3709 XXXX AS3709 – 68 AS3709 K2V0-xx XXXX ams Datasheet, Confidential: 2013-Aug [1-02] Pa c k a g e D r a w i n g s & M a r k i n g s Figure 96: WL-CSP Code XXXX Encoded Datecode Figure 97: Start-up Revision Code Revision Code Sequence K2V0-ES Engineering samples, no sequence programmed or sequence programmed on request “empty” Standard programming (no sequence programmed) K2V0-00 Standard programming (no sequence programmed) K2V0-xx Customer specified sequence programmed during production test ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 69 RoHS Compliant & ams Green Statement RoHS Compliant & ams Green Statement RoHS: The term RoHS compliant means that ams products fully comply with current RoHS directive. Our semiconductor products do not contain any chemicals for all 6 substance categories, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, RoHS compliant products are suitable for use in specified lead-free processes. ams Green (RoHS compliant and no Sb/Br): ams Green defines that additionally to RoHS compliance, our products are free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material). Important Information: The information provided in this statement represents ams knowledge and belief as of the date that it is provided. ams bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. ams has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. ams and ams suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release. AS3709 – 70 ams Datasheet, Confidential: 2013-Aug [1-02] Ordering & Contac t Information Ordering & Contact Information Figure 98: Ordering Information Ordering Code Marking Sequence Description Delivery Form AS3709BQFR-ES K2V0-ES Sequence programmable on request μPMIC with 5 DCDC and 2 LDOs Tray 32-pin QFN 4x4 AS3709BQFM-00 K2V0-00 Default sequence μPMIC with 5 DCDC and 2 LDOs Tape & Reel 32-pin QFN 4x4 AS3709BQFM-xx K2V0-xx Customer specified sequence μPMIC with 5 DCDC and 2 LDOs Tape & Reel 32-pin QFN 4x4 K2V0-ES Sequence programmable on request μPMIC with 5 DCDC and 2 LDOs Tray 36-pin WL-CSP 0.4mm pitch K2V0-xx Customer specified sequence μPMIC with 5 DCDC and 2 LDOs Tape & Reel 36-pin WL-CSP 0.4mm pitch AS3709BWLR-ES (Note:) AS3709BWLT-xx (Note:) Package Note: On request. Buy our products or get free samples online at: www.ams.com/ICdirect Technical Support is available at: www.ams.com/Technical-Support For further information and requests, e-mail us at: [email protected] For sales offices, distributors and representatives, please visit: www.ams.com/contact Headquarters ams AG Tobelbaderstrasse 30 8141 Unterpremstaetten Austria, Europe Tel: +43 (0) 3136 500 0 Website: www.ams.com ams Datasheet, Confidential: 2013-Aug [1-02] AS3709 – 71 Copyrights & Disclaimer Copyrights & Disclaimer Copyright ams AG, Tobelbader Strasse 30, 8141 Unterpremstaetten, Austria-Europe. Trademarks Registered. All rights reserved. The material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner. Devices sold by ams AG are covered by the warranty and patent indemnification provisions appearing in its Term of Sale. ams AG makes no warranty, express, statutory, implied, or by description regarding the information set forth herein. ams AG reserves the right to change specifications and prices at any time and without notice. Therefore, prior to designing this product into a system, it is necessary to check with ams AG for current information. This product is intended for use in commercial applications. Applications requiring extended temperature range, unusual environmental requirements, or high reliability applications, such as military, medical life-support or life-sustaining equipment are specifically not recommended without additional processing by ams AG for each application. This Product is provided by ams “AS IS” and any express or implied warranties, including, but not limited to the implied warranties of merchantability and fitness for a particular purpose are disclaimed. ams AG shall not be liable to recipient or any third party for any damages, including but not limited to personal injury, property damage, loss of profits, loss of use, interruption of business or indirect, special, incidental or consequential damages, of any kind, in connection with or arising out of the furnishing, performance or use of the technical data herein. No obligation or liability to recipient or any third party shall arise or flow out of ams AG rendering of technical or other services. AS3709 – 72 ams Datasheet, Confidential: 2013-Aug [1-02] Reference Guide Reference Guide 1 1 2 2 General Description Key Benefits & Features Applications Block Diagram 3 6 8 Pin Assignment Absolute Maximum Ratings Electrical Characteristics 9 Detailed Description Power Management Functions Step Down DCDC Converter Mode Settings Low-Ripple, Low-Noise Operation High-Efficiency Operation (Default Setting) Low Power Mode Operation (Automatically Controlled) DVM (Dynamic Voltage Management) Fast Regulation Mode Selectable Frequency Operation 100% PMOS ON Mode for Low Dropout Regulation Step Down Converter Configuration Modes Parameters Universal IO LDO Regulators Parameter Low Power LDO V2_5 Regulator Parameter 9 10 10 10 11 11 12 12 12 12 15 21 22 23 23 24 24 24 24 26 26 26 26 27 27 27 27 27 29 29 29 30 31 31 31 31 31 32 32 33 33 ams Datasheet, Confidential: 2013-Aug [1-02] Detailed Description System Functions Start-up Normal Start-up Parameter Reset RESET Reasons Voltage Detection Power OFF Software Forced Reset External Triggered Reset Over-temperature Reset Long ON-key Press Parameter Stand-by Internal References Low Power Mode GPIO Pins IO Functions Normal IO Operation: Interrupt Output VSUP_low Output GPIO Interrupt Input Vselect Input Stand-by and Vselect Input PWRGOOD Output Supervisor AS3709 – 73 Reference Guide AS3709 – 74 33 34 34 34 35 36 37 38 Temperature Supervision Interrupt Generation 2-Wire-Serial Control Interface Feature List I²C Protocol I²C Write Access I²C Read Access I²C Parameter 40 42 Register Description Detailed Register Description 63 67 71 72 73 Application Information Package Drawings & Markings RoHS Compliant & ams Green Statement Ordering & Contact Information Copyrights & Disclaimer ams Datasheet, Confidential: 2013-Aug [1-02]