ZHCSJX9 June 2019 TPS652170
PRODUCTION DATA.
请参考 PDF 数据表获取器件具体的封装图。
PARAMETER | TEST CONDITIONS | MIN | TYP | MAX | UNIT | ||
---|---|---|---|---|---|---|---|
INPUT VOLTAGE AND CURRENTS | |||||||
VBAT | Battery input voltage range | USB or AC supply connected | 0 | 5.5 | V | ||
USB and AC not connected | 2.75 | 5.5 | |||||
VAC | AC adapter input voltage range | Valid range for charging | 4.3 | 5.8 | V | ||
VUSB | USB input voltage range | Valid range for charging | 4.3 | 5.8 | V | ||
VUVLO | Undervoltage lockout | Measured in respect to VBAT; supply falling;
VAC = VUSB = 0 V |
UVLO[1:0] = 00b | 2.73 | V | ||
UVLO[1:0] = 01b | 2.89 | ||||||
UVLO[1:0] = 10b | 3.18 | ||||||
UVLO[1:0] = 11b | 3.3 | ||||||
UVLO accuracy | –2% | 2% | |||||
UVLO deglitch time(3) | 4 | 6 | ms | ||||
VOFFSET | AC and USB UVLO offset | VBAT < VUVLO; Device shuts down when VAC, VUSB drop below VUVLO + VOFFSET | 200 | mV | |||
IOFF | OFF current,
Total current into VSYS, VINDCDCx, VINLDO |
All rails disabled, TA = 27°C | 6 | µA | |||
ISLEEP | Sleep current,
Total current into VSYS, VINDCDCx, VINLDO |
LDO1 and LDO2 enabled, no load.
All other rails disabled. VSYS = 4 V, TA = 0.105°C |
80 | 106 | µA | ||
VIN(DT) | AC and USB voltage-detection threshold | VBAT > VUVLO, AC and USB valid when VAC-USB – VBAT > VIN(DT) | 190 | mV | |||
VBAT < VUVLO, AC and USB valid when VAC-USB > VIN(DT) | 4.3 | V | |||||
VIN(NDT) | AC and USB voltage-removal detection threshold | VBAT > VUVLO, AC and USB invalid when VAC/USB – VBAT < VIN(DT) | 125 | mV | |||
VBAT < VUVLO, AC and USB invalid when VAC-USB < VIN(DT) | VUVLO + VOFFSET | V | |||||
tRISE | VAC, VUSB rise time | Voltage rising from 100 mV to 4.5 V. If rise time is exceeded, device may not power up. | 50 | ms | |||
tDG(DT) | Power detected deglitch(3) | AC or USB voltage increasing | 22.5 | ms | |||
VIN(OVP) | Input overvoltage detection threshold | USB and AC input | 5.8 | 6 | 6.4 | V | |
POWER PATH TIMING | |||||||
tSW(PSEL) | Switching from AC to USB(3) | 150 | µs | ||||
POWER PATH MOSFET CHARACTERISTICS | |||||||
VDO, AC | AC input switch dropout voltage | IAC[1:0] = 11b (2.5 A), ISYS = 1 A | 150 | mV | |||
VDO, USB | USB input switch dropout voltage | IUSB[1:0] = 01b (500 mA), ISYS = 500 mA | 100 | mV | |||
IUSB[1:0] = 10b (1300 mA), ISYS = 800 mA | 160 | ||||||
VDO, BAT | Battery switch dropout voltage | VBAT = 3 V, IBAT = 1 A | 60 | mV | |||
POWER PATH INPUT CURRENT LIMITS | |||||||
IACLMT | Input current limit; AC pin | IAC[1:0] = 00b | 90 | 130 | mA | ||
IAC[1:0] = 01b | 480 | 580 | |||||
IAC[1:0] = 10b | 1000 | 1500 | |||||
IAC[1:0] = 11b | 2000 | 2500 | |||||
IUSBLMT | Input current limit; USB pin | IUSB[1:0] = 00b | 90 | 100 | mA | ||
IUSB[1:0] = 01b | 460 | 500 | |||||
IUSB[1:0] = 10b | 1000 | 1300 | |||||
IUSB[1:0] = 11b | 1500 | 1800 | |||||
IBAT | Battery load current(3) | 2 | A | ||||
POWER PATH BATTERY SUPPLEMENT DETECTION | |||||||
VBSUP | Battery supplement threshold | VSYS ≤ VBAT – VBSUP1,
VSYS falling IUSB[1:0] = 10b |
40 | mV | |||
Battery supplement hysteresis | VSYS rising | 20 | |||||
POWER PATH BATTERY PROTECTION | |||||||
VBAT(SC) | BAT pin short-circuit detection threshold | 1.3 | 1.5 | 1.7 | V | ||
IBAT(SC) | Source current for BAT pin short-circuit detection | 7.5 | mA | ||||
INPUT BASED DYNAMIC POWER PATH MANAGEMENT (DPPM) | |||||||
VDPPM | Threshold at which DPPM loop is enabled | I2C selectable | 3.5 | 4.25 | V | ||
BATTERY CHARGER | |||||||
VOREG | Battery charger voltage | I2C selectable | 4.1 | 4.25 | V | ||
Battery charger accuracy | –2% | 1% | |||||
VLOWV | Precharge to fast-charge transition threshold | VPRECHG = 0b | 2.9 | V | |||
VPRECHG = 1b | 2.5 | ||||||
tDGL1(LOWV) | Deglitch time on precharge to fast-charge transition(3) | 25 | ms | ||||
tDGL2(LOWV) | Deglitch time on fast-charge to precharge transition(3) | 25 | ms | ||||
ICHG | Battery fast charge current range
VOREG > VBAT > VLOWV, VIN = VUSB = 5 V |
ICHRG[1:0] = 00b | 300 | mA | |||
ICHRG[1:0] = 01b | 400 | ||||||
ICHRG[1:0] = 10b | 450 | 500 | 550 | ||||
ICHRG[1:0] = 11b | 700 | ||||||
IPRECHG | Precharge current | ICHRG[1:0] = 00b | 30 | mA | |||
ICHRG[1:0] = 01b | 40 | ||||||
ICHRG[1:0] = 10b | 25 | 50 | 75 | ||||
ICHRG[1:0] = 11b | 70 | ||||||
ITERM | Charge current value for termination detection threshold (fraction of ICHG) | TERMIF[1:0] = 00b | 2.5% | ||||
TERMIF[1:0] = 01b | 3% | 7.5% | 10% | ||||
TERMIF[1:0] = 10b | 15% | ||||||
TERMIF[1:0] = 11b | 18% | ||||||
tDGL(TERM) | Deglitch time, termination detected(3) | 125 | ms | ||||
VRCH | Recharge detection threshold | Voltage below VOREG | 150 | 100 | 70 | mV | |
tDGL(RCH) | Deglitch time, recharge threshold detected(3) | 125 | ms | ||||
IBAT(DET) | Sink current for battery detection | TJ = 27°C | 3 | 7.5 | 10 | mA | |
tDET | Battery detection timer. IBAT(DET) is pulled from the battery for tDET. If BAT voltage stays above VRCH threshold the battery is connected.(3) | VBAT < VRCH; | 250 | ms | |||
tCHG | Charge safety timer(3) | Safety timer range, thermal and DPPM not active, selectable by I2C | 4 | 8 | h | ||
tPRECHG | Precharge timer(3) | Pre charge timer, thermal and DPPM loops not active, selectable by I2C | PCHRGT = 0b | 30 | 60 | min | |
PCHRGT = 1b | 60 | ||||||
BATTERY NTC MONITOR | |||||||
tTHON | Thermistor power on time at charger off, sampling mode on | 10 | ms | ||||
tTHOFF | Thermistor power sampling period at charger off, sampling mode on | 1 | s | ||||
RNTC_PULL | Pullup resistor from thermistor to Internal LDO, I2C selectable | NTC_TYPE = 1 (10-kΩ NTC) | 7.35 | kΩ | |||
NTC_TYPE = 0 (100-kΩ NTC) | 60.5 | ||||||
Accuracy | TA = 27°C | –3% | 3% | ||||
VLTF | Low-temperature failure threshold | Temperature falling | 1660 | mV | |||
Temperature rising | 1610 | ||||||
VHTF | High-temperature failure threshold | Temperature falling | TRANGE = 0b | 910 | mV | ||
Temperature rising | 860 | ||||||
Temperature falling | TRANGE = 1b | 667 | |||||
Temperature rising | 622 | ||||||
VDET | Thermistor detection threshold | 1750 | 1850 | mV | |||
tBATDET | Thermistor not detected. Battery not present deglitch(3) | 26 | ms | ||||
THERMAL REGULATION | |||||||
TJ(REG) | Temperature regulation limit, temperature at which charge current is decreased | 111 | 123 | °C | |||
DCDC1 (BUCK) | |||||||
VIN | Input voltage range | VIN_DCDC1 pin | 2.7 | VSYS | V | ||
IQ,SLEEP | Quiescent current in SLEEP mode | No load, VSYS = 4 V, TA = 25°C | 30 | µA | |||
VOUT | Output voltage range | External resistor divider (XADJ1 = 1b) | 0.6 | VIN | V | ||
I2C selectable in 25-mV steps
(XADJ1 = 0b) |
0.9 | 1.8(1) | |||||
DC output voltage accuracy | VIN = VOUT + 0.3 V to 5.8 V;
0 mA ≤ IOUT ≤ 1.2 A |
–2% | 3% | ||||
Power-save mode (PSM) ripple voltage | IOUT = 1 mA, PFM mode
L = 2.2 µH, COUT = 20 µF |
40 | mVpp | ||||
IOUT | Output current range | 0 | 1.2 | A | |||
rDS(on) | High-side MOSFET on-resistance | VIN = 2.7 V | 170 | mΩ | |||
Low-side MOSFET on-resistance | VIN = 2.7 V | 120 | |||||
ILEAK | High-side MOSFET leakage current | VIN = 5.8 V | 2 | µA | |||
Low-side MOSFET leakage current | VDS = 5.8 V | 1 | |||||
ILIMIT | Current limit (high- and low-side MOSFET). | 2.7 V < VIN < 5.8 V | 1.6 | A | |||
fSW | Switching frequency | 1.95 | 2.25 | 2.55 | MHz | ||
VFB | Feedback voltage | XADJ = 1b | 600 | mV | |||
tSS | Soft-start time | Time to ramp VOUT from 5% to 95%, no load | 750 | µs | |||
RDIS | Internal discharge resistor at L1(2) | 250 | Ω | ||||
L | Inductor | 1.5 | 2.2 | µH | |||
COUT | Output capacitor | Ceramic | 10 | 22 | µF | ||
ESR of output capacitor | 20 | mΩ | |||||
DCDC2 (BUCK) | |||||||
VIN | Input voltage range | VIN_DCDC2 pin | 2.7 | VSYS | V | ||
IQ,SLEEP | Quiescent current in SLEEP mode | No load, VSYS = 4 V, TA = 25°C | 30 | µA | |||
VOUT | Output voltage range | External resistor divider (XADJ2 = 1b) | 0.6 | VIN | V | ||
I2C selectable in 25-mV steps
(XADJ2 = 0b) |
0.9 | 3.3 | |||||
DC output voltage accuracy | VIN = VOUT + 0.3 V to 5.8 V;
0 mA ≤ IOUT ≤ 1.2 A |
–2% | 3% | ||||
Power-save mode (PSM) ripple voltage | IOUT = 1 mA, PFM mode
L = 2.2 µH, COUT = 20 µF |
40 | mVpp | ||||
IOUT | Output current range | 0 | 1.2 | A | |||
rDS(on) | High-side MOSFET on-resistance | VIN = 2.7 V | 170 | mΩ | |||
Low-side MOSFET on-resistance | VIN = 2.7 V | 120 | |||||
ILEAK | High-side MOSFET leakage current | VIN = 5.8 V | 2 | µA | |||
Low-side MOSFET leakage current | VDS = 5.8 V | 1 | |||||
ILIMIT | Current limit (high and low side MOSFET). | 2.7 V < VIN < 5.8 V | 1.6 | A | |||
fSW | Switching frequency | 1.95 | 2.25 | 2.55 | MHz | ||
VFB | Feedback voltage | XADJ = 1b | 600 | mV | |||
tSS | Soft-start time | Time to ramp VOUT from 5% to 95%, no load | 750 | µs | |||
RDIS | Internal discharge resistor at L2 | 250 | Ω | ||||
L | Inductor | 1.5 | 2.2 | µH | |||
COUT | Output capacitor | Ceramic | 10 | 22 | µF | ||
ESR of output capacitor | 20 | mΩ | |||||
DCDC3 (BUCK) | |||||||
VIN | Input voltage range | VIN_DCDC3 pin | 2.7 | VSYS | V | ||
IQ,SLEEP | Quiescent current in SLEEP mode | No load, VSYS = 4 V, TA = 25°C | 30 | µA | |||
VOUT | Output voltage range | External resistor divider (XADJ3 = 1b) | 0.6 | VIN | V | ||
I2C selectable in 25-mV steps
(XADJ3 = 0b) |
0.9 | 1.5(1) | |||||
DC output voltage accuracy | VIN = VOUT + 0.3 V to 5.8 V;
0 mA ≤ IOUT ≤ 1.2 A |
–2% | 3% | ||||
Power save mode (PSM) ripple voltage | IOUT = 1 mA, PFM mode
L = 2.2 µH, COUT = 20 µF |
40 | mVpp | ||||
IOUT | Output current range | 0 | 1.2 | A | |||
rDS(on) | High-side MOSFET on-resistance | VIN = 2.7 V | 170 | mΩ | |||
Low side MOSFET on-resistance | VIN = 2.7 V | 120 | |||||
ILEAK | High-side MOSFET leakage current | VIN = 5.8 V | 2 | µA | |||
Low-side MOSFET leakage current | VDS = 5.8 V | 1 | |||||
ILIMIT | Current limit (high- and low-side MOSFET). | 2.7 V < VIN < 5.8 V | 1.6 | A | |||
fSW | Switching frequency | 1.95 | 2.25 | 2.55 | MHz | ||
VFB | Feedback voltage | XADJ = 1b | 600 | mV | |||
tSS | Soft-start time | Time to ramp VOUT from 5% to 95%, no load | 750 | µs | |||
RDIS | Internal discharge resistor at L1, L2 | 250 | Ω | ||||
L | Inductor | 1.5 | 2.2 | µH | |||
COUT | Output capacitor | Ceramic | 10 | 22 | µF | ||
ESR of output capacitor | 20 | mΩ | |||||
LDO1, LDO2 | |||||||
VIN | Input voltage range | 1.8 | 5.8 | V | |||
IQ,SLEEP | Quiescent current in SLEEP mode | No load, VSYS = 4 V, TA = 25°C | 5 | µA | |||
VOUT | Output voltage range | LDO1, I2C selectable | 1 | 3.3 | V | ||
LDO2, I2C selectable | 0.9 | 3.3 | |||||
DC output voltage accuracy | IOUT = 10 mA, VIN > VOUT + 200 mV,
VOUT > 0.9 V |
–2% | 2% | ||||
Line regulation | VIN = 2.7 V - 5.5 V, VOUT = 1.2 V,
IOUT = 100 mA |
–1% | 1% | ||||
Load regulation | IOUT = 1 mA - 100 mA, VOUT = 1.2 V,
VIN = 3.3 V |
–1% | 1% | ||||
IOUT = 0 mA - 1 mA, VOUT = 1.2 V,
VIN = 3.3 V |
–2.5% | 2.5% | |||||
IOUT | Output current range | SLEEP state | 0 | 1 | mA | ||
ACTIVE state | 0 | 100 | |||||
ISC | Short circuit current limit | Output shorted to GND | 100 | 250 | mA | ||
VDO | Dropout voltage | IOUT = 100 mA, VIN = 3.3 V | 200 | mV | |||
RDIS | Internal discharge resistor at output | 430 | Ω | ||||
COUT | Output capacitor | Ceramic | 2.2 | µF | |||
ESR of output capacitor | 20 | mΩ | |||||
LS1 OR LDO3, AND LS2 OR LDO4, CONFIGURED AS LDOs | |||||||
VIN | Input voltage range | 2.7 | 5.8 | V | |||
IQ,SLEEP | Quiescent current in SLEEP mode | No load, VSYS = 4 V, TA = 25°C | 30 | µA | |||
VOUT | Output voltage range | LS1LDO3 = 1b, LS2LDO4 = 1b
I2C selectable |
1.5 | 3.3 | V | ||
DC output voltage accuracy | IOUT = 10 mA, VIN > VOUT + 200 mV,
VOUT > 1.8 V |
–2% | 2% | ||||
Line regulation | VIN = 2.7 V - 5.5 V, VOUT = 1.8 V,
IOUT = 200 mA |
–1% | 1% | ||||
Load regulation | IOUT = 1 mA - 200 mA, VOUT = 1.8 V,
VIN = 3.3 V |
–1% | 1% | ||||
VDO | Dropout voltage | IOUT = 200 mA, VIN = 3.3 V | 200 | mV | |||
RDIS | Internal discharge resistor at output(2) | 375 | Ω | ||||
COUT | Output capacitor | Ceramic | 8 | 10 | 12 | µF | |
ESR of output capacitor | 20 | mΩ | |||||
LS1 OR LDO3, AND LS2 OR LDO4, CONFIGURED AS LOAD SWITCHES | |||||||
VIN | Input voltage range | LS1_VIN, LS2_VIN pins | 1.8 | 5.8 | V | ||
RDS(ON) | P-channel MOSFET on-resistance | VIN = 1.8 V, over full temperature range | 300 | 650 | mΩ | ||
ISC | Short circuit current limit | Output shorted to GND | 200 | 280 | mA | ||
RDIS | Internal discharge resistor at output | 375 | Ω | ||||
COUT | Output capacitor | Ceramic | 1 | 10 | 12 | µF | |
ESR of output capacitor | 20 | mΩ | |||||
WLED BOOST | |||||||
VIN | Input voltage range | 2.7 | 5.8 | V | |||
VOUT | Max output voltage | ISINK = 20 mA | 32 | V | |||
VOVP | Output overvoltage protection | 37 | 38 | 39 | V | ||
RDS(ON) | N-channel MOSFET on-resistance | VIN = 3.6 V | 0.6 | Ω | |||
ILEAK | N-channel leakage current | VDS = 25 V, TA = 25°C | 2 | µA | |||
ILIMIT | N-channel MOSFET current limit | 1.6 | 1.9 | A | |||
fSW | Switching frequency | 1.125 | MHz | ||||
IINRUSH | Inrush current on start-up | VIN = 3.6 V, 1% duty cycle setting | 1.1 | A | |||
VIN = 3.6 V, 100% duty cycle setting | 2.1 | ||||||
L | Inductor | 18 | µH | ||||
COUT | Output capacitor | Ceramic | 4.7 | µF | |||
ESR of output capacitor | 20 | mΩ | |||||
WLED CURRENT SINK1, SINK2 | |||||||
VSINK1,2 | Overvoltage protection threshold at ISINK1, ISINK2 pins | 19 | V | ||||
VDO, SINK1,2 | Current sink drop-out voltage | Measured from ISINK to GND | 400 | mV | |||
VISET1,2 | ISET1, ISET2 pin voltage | 1.24 | V | ||||
ISINK1,2 | WLED current range (ISINK1, ISINK2) | 1 | 25 | mA | |||
WLED sink current | RISET = 130.0 kΩ | 10 | |||||
RISET = 86.6 kΩ | 15 | ||||||
RISET = 64.9 kΩ | 20 | ||||||
RISET = 52.3 kΩ | 25 | ||||||
DC current set accuracy | ISINK = 5 mA to 25 mA, 100% duty cycle | –5% | 5% | ||||
DC current matching | RSET1 = 52.3 kΩ, ISINK = 25 mA,
VBAT = 3.6 V, 100% duty cycle |
–5% | 5% | ||||
RSET1 = 130 kΩ, ISINK = 10 mA,
VBAT = 3.6 V, 100% duty cycle |
–5% | 5% | |||||
fPWM | PWM dimming frequency | FDIM[1:0] = 00b | 100 | Hz | |||
FDIM[1:0] = 01b | 200 | ||||||
FDIM[1:0] = 10b | 500 | ||||||
FDIM[1:0] = 11b | 1000 | ||||||
ANALOG MULTIPLEXER | |||||||
g | Gain, VBAT (VBAT / VOUT,MUX); VSYS (VSYS / VOUT,MUX) | 3 | V/V | ||||
Gain, VTS (VTS / VOUT,MUX); MUX_IN (VMUX_IN / VMUX_OUT) | 1 | ||||||
Gain, VICHARGE (VOUT,MUX / VICHARGE) | ICHRG[1:0] = 00b | 7.575 | V/A | ||||
ICHRG[1:0] = 01b | 5.625 | ||||||
ICHRG[1:0] = 10b | 4.5 | ||||||
ICHRG[1:0] = 11b | 3.214 | ||||||
VOUT | Buffer headroom (VSYS – VMUX_OUT) | VSYS = 3.6 V, MUX[2:0] = 101b
(VMUX_IN – VMUX_OUT) / VMUX_IN > 1% |
0.7 | 1 | V | ||
ROUT | Output Impedance | 180 | Ω | ||||
ILEAK | Leakage current | MUX[2:0] = 000b (HiZ), VMUX = 2.25 V | 1 | µA | |||
LOGIC LEVELS AND TIMING CHARACTERISTICS
(SCL, SDA, PB_IN, PGOOD, LDO_PGOOD, PWR_EN, nINT, nWAKEUP, nRESET) |
|||||||
PGTH | PGOOD comparator treshold,
All DC/DC converters and LDOs(3) |
Output voltage falling, % of set voltage | 90% | ||||
Output voltage rising, % of set voltage | 95% | ||||||
PGDG | PGOOD deglitch time | Output voltage falling, DCDC1, DCDC2, DCDC3 | 2 | 4 | ms | ||
Output voltage falling, LDO1, LDO2, LDO3, LDO4 | 1 | 2 | |||||
PGDLY | PGOOD delay time | PGDLY[1:0] = 00b | 20 | ms | |||
PGDLY[1:0] = 01b | 100 | ||||||
PGDLY[1:0] = 10b | 200 | ||||||
PGDLY[1:0] = 11b | 400 | ||||||
tHRST | PB-IN hard-reset-detect time(3) | 8 | s | ||||
tDG | PB_IN pin deglitch time(3) | 50 | ms | ||||
PWR_EN pin deglitch time(3) | 50 | ||||||
nRESET pin deglitch time(3) | 30 | ||||||
RPULLUP | PB_IN internal pullup resistor | 100 | kΩ | ||||
nRESET internal pullup resistor | 100 | ||||||
VIH | High-level input voltage
PB_IN, SCL, SDA, PWR_EN, nRESET |
1.2 | VIN | V | |||
VIL | Low-level input voltage
PB_IN, SCL, SDA, PWR_EN, nRESET |
0 | 0.4 | V | |||
IBIAS | Input bias current
PB_IN, SCL, SDA |
0.01 | 1 | µA | |||
VOL | Output low voltage | nINT, nWAKEUP, IO = 1 mA | 0.3 | V | |||
PGOOD, LDO_PGOOD, IO = 1 mA | 0.3 | ||||||
VOH | Output high voltage | PGOOD, LDO_PGOOD, IO = 1 mA | VIO – 0.3 | V | |||
ILEAK | Pin leakage current
nINT, nWAKEUP |
Pin pulled up to 3.3-V supply | 0.2 | µA | |||
I2C slave address | 0x24h | ||||||
OSCILLATOR | |||||||
fOSC | Oscillator frequency | 9 | MHz | ||||
Oscillator frequency accuracy | TA = –40°C to 105°C | –10% | 10% | ||||
OVERTEMPERATURE SHUTDOWN | |||||||
TOTS | Overtemperature shutdown | Increasing junction temperature | 150 | °C | |||
Hysteresis | Decreasing junction temperature | 20 | °C |