SWCS037I May   2008  – January 2015 TPS65920 , TPS65930

PRODUCTION DATA.  

  1. 1Device Overview
    1. 1.1 Features
    2. 1.2 Applications
    3. 1.3 Description
    4. 1.4 Functional Block Diagram
  2. 2Revision History
  3. 3Terminal Configuration and Functions
    1. 3.1 Pin Diagram
    2. 3.2 Pin Attributes
    3. 3.3 Signal Descriptions
  4. 4Specifications
    1. 4.1 Absolute Maximum Ratings
    2. 4.2 ESD Ratings
    3. 4.3 Recommended Operating Conditions
    4. 4.4 Thermal Characteristics for ZCH Package
    5. 4.5 Minimum Voltages and Associated Currents
    6. 4.6 Digital I/O Electrical Characteristics
    7. 4.7 Timing Requirements and Switching Characteristics
      1. 4.7.1 Timing Parameters
      2. 4.7.2 Target Frequencies
      3. 4.7.3 I2C Timing
      4. 4.7.4 Audio Interface: TDM/I2S Protocol
        1. 4.7.4.1 I2S Right- and Left-Justified Data Format
        2. 4.7.4.2 TDM Data Format
      5. 4.7.5 JTAG Interfaces
  5. 5Detailed Description
    1. 5.1 Power Module
      1. 5.1.1 Power Providers
        1. 5.1.1.1  VDD1 DC-DC Regulator
          1. 5.1.1.1.1 VDD1 DC-DC Regulator Characteristics
          2. 5.1.1.1.2 External Components and Application Schematics
        2. 5.1.1.2  VDD2 DC-DC Regulator
          1. 5.1.1.2.1 VDD2 DC-DC Regulator Characteristics
          2. 5.1.1.2.2 External Components and Application Schematics
        3. 5.1.1.3  VIO DC-DC Regulator
          1. 5.1.1.3.1 VIO DC-DC Regulator Characteristics
          2. 5.1.1.3.2 External Components and Application Schematics
        4. 5.1.1.4  VDAC LDO Regulator
        5. 5.1.1.5  VPLL1 LDO Regulator
        6. 5.1.1.6  VMMC1 LDO Regulator
        7. 5.1.1.7  VAUX2 LDO Regulator
        8. 5.1.1.8  Output Load Conditions
        9. 5.1.1.9  Charge Pump
        10. 5.1.1.10 USB LDO Short-Circuit Protection Scheme
      2. 5.1.2 Power References
      3. 5.1.3 Power Control
        1. 5.1.3.1 Backup Battery Charger
        2. 5.1.3.2 Battery Monitoring and Threshold Detection
          1. 5.1.3.2.1 Power On/Power Off and Backup Conditions
        3. 5.1.3.3 VRRTC LDO Regulator
      4. 5.1.4 Power Consumption
      5. 5.1.5 Power Management
        1. 5.1.5.1 Boot Modes
        2. 5.1.5.2 Process Modes
          1. 5.1.5.2.1 MC021 Mode
        3. 5.1.5.3 Power-On Sequence
          1. 5.1.5.3.1 Timing Before Sequence_Start
          2. 5.1.5.3.2 Power-On Sequence
          3. 5.1.5.3.3 Power On in Slave_C021 Mode
        4. 5.1.5.4 Power-Off Sequence
          1. 5.1.5.4.1 Power-Off Sequence
    2. 5.2 Real-Time Clock and Embedded Power Controller
      1. 5.2.1 RTC
        1. 5.2.1.1 Backup Battery
      2. 5.2.2 EPC
    3. 5.3 USB Transceiver
      1. 5.3.1 Features
      2. 5.3.2 HS USB Port Timing
      3. 5.3.3 USB-CEA Carkit Port Timing
      4. 5.3.4 PHY Electrical Characteristics
        1. 5.3.4.1 HS Differential Receiver
        2. 5.3.4.2 HS Differential Transmitter
        3. 5.3.4.3 CEA/UART Driver
        4. 5.3.4.4 Pullup/Pulldown Resistors
      5. 5.3.5 OTG Electrical Characteristics
        1. 5.3.5.1 OTG VBUS Electrical Characteristics
        2. 5.3.5.2 OTG ID Electrical Characteristics
    4. 5.4 MADC
      1. 5.4.1 General Description
      2. 5.4.2 MADC Electrical Characteristics
      3. 5.4.3 Channel Voltage Input Range
        1. 5.4.3.1 Sequence Conversion Time (Real-Time or Nonaborted Asynchronous)
    5. 5.5 LED Drivers
      1. 5.5.1 General Description
    6. 5.6 Keyboard
      1. 5.6.1 Keyboard Connection
    7. 5.7 Clock Specifications
      1. 5.7.1 Clock Features
      2. 5.7.2 Input Clock Specifications
        1. 5.7.2.1 Clock Source Requirements
        2. 5.7.2.2 HFCLKIN
        3. 5.7.2.3 32-kHz Input Clock
          1. 5.7.2.3.1 External Crystal Description
          2. 5.7.2.3.2 External Clock Description
      3. 5.7.3 Output Clock Specifications
        1. 5.7.3.1 32KCLKOUT Output Clock
        2. 5.7.3.2 HFCLKOUT Output Clock
        3. 5.7.3.3 Output Clock Stabilization Time
    8. 5.8 Debouncing Time
    9. 5.9 External Components
  6. 6Audio/Voice Module (TPS65930 Device Only)
    1. 6.1 Audio/Voice Downlink (RX) Module
      1. 6.1.1 Predriver for External Class-D Amplifier
        1. 6.1.1.1 Predriver Output Characteristics
        2. 6.1.1.2 External Components and Application Schematics
      2. 6.1.2 Vibrator H-Bridge
        1. 6.1.2.1 Vibrator H-Bridge Output Characteristics
        2. 6.1.2.2 External Components and Application Schematics
      3. 6.1.3 Carkit Output
      4. 6.1.4 Digital Audio Filter Module
      5. 6.1.5 Boost Stage
    2. 6.2 Audio Uplink (TX) Module
      1. 6.2.1 Microphone Bias Module
        1. 6.2.1.1 Analog Microphone Bias Module Characteristics
        2. 6.2.1.2 Silicon Microphone Module Characteristics
      2. 6.2.2 FM Radio/Auxiliary Input
        1. 6.2.2.1 External Components
      3. 6.2.3 Uplink Characteristics
      4. 6.2.4 Microphone Amplification Stage
      5. 6.2.5 Carkit Input
      6. 6.2.6 Digital Audio Filter Module
  7. 7Device and Documentation Support
    1. 7.1 Device Support
      1. 7.1.1 Development Support
      2. 7.1.2 Device Nomenclature
    2. 7.2 Community Resources
    3. 7.3 Related Links
    4. 7.4 Trademarks
    5. 7.5 Electrostatic Discharge Caution
    6. 7.6 Export Control Notice
    7. 7.7 Glossary
    8. 7.8 Additional Acronyms
  8. 8Mechanical, Packaging, and Orderable Information
    1. 8.1 Packaging Information

パッケージ・オプション

メカニカル・データ(パッケージ|ピン)
サーマルパッド・メカニカル・データ
発注情報

5 Detailed Description

5.1 Power Module

This section describes the electrical characteristics of the voltage regulators and timing characteristics of the supplies digitally controlled in the TPS65920 and TPS65930 devices.

Figure 5-1 is the power provider block diagram.

swcs037-010.gif
Two internal regulators, VRRTC and VBRTC, are not shown. VRRTC provides power to the RTC, and VBRTC is not used in this configuration.
Figure 5-1 Power Provider Block Diagram

NOTE

For the component values, see Table 5-48.

5.1.1 Power Providers

Table 5-1 summarizes the power providers.

Table 5-1 Summary of the Power Providers

NAME USAGE TYPE VOLTAGE RANGE (V) DEFAULT VOLTAGE MAXIMUM CURRENT
VAUX2 External LDO 1.3, 1.5, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.8 1.8 V 100 mA
VMMC1 External LDO 1.85, 2.85, 3.0, 3.15 3.0 V 220 mA
VPLL1 External LDO 1.0, 1.2, 1.3, 1.8, 2.8, 3.0 1.8 V 40 mA
VDAC External LDO 1.2, 1.3, 1.8 1.8 V 70 mA
VIO External SMPS 1.8, 1.85 1.8 V 700 mA
VDD1 External SMPS 0.6 ... 1.45 1.2 V 1200 mA
VDD2 External SMPS 0.6 ... 1.5 1.2 V 600 mA
VINTANA1 Internal LDO 1.5 1.5 V 50 mA
VINTANA2 Internal LDO 2.5, 2.75 2.75 V 250 mA
VINTDIG Internal LDO 1.0, 1.2, 1.3, 1.5 1.5 V 80 mA
USBCP Internal Charge pump 5 5 V 100 mA
VUSB1V5 Internal LDO 1.5 1.5 V 30 mA
VUSB1V8 Internal LDO 1.8 1.8 V 30 mA
VUSB3V1 Internal LDO 3.1 3.1 V 15 mA
VRRTC Internal LDO 1.5 1.5 V 30 mA
VBRTC Internal LDO 1.3 1.3 V 100 μA

5.1.1.1 VDD1 DC-DC Regulator

5.1.1.1.1 VDD1 DC-DC Regulator Characteristics

The VDD1 DC-DC regulator is a stepdown DC-DC converter with a configurable output voltage. The programming of the output voltage and the characteristics of the DC-DC converter are SmartReflex-compatible. The regulator can be put in sleep mode to reduce its leakage (PFM) or in power-down mode when it is not in use. Table 5-3 describes the regulator characteristics.

Table 5-2 Part Names With Corresponding VDD1 Current Support

DEVICE NAME VDD1 CURRENT SUPPORT
TPS65920A2ZCH (some bug fixes, see errata) 1.2 A
TPS65920A2ZCHR (some bug fixes, see errata) 1.2 A
TPS65930A2ZCH (some bug fixes, see errata) 1.2 A
TPS65930A2ZCHR (some bug fixes, see errata) 1.2 A

Table 5-3 VDD1 DC-DC Regulator Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
Input voltage range 2.7 3.6 4.5 V
Output voltage 0.6 1.45 V
Output voltage step Covering the 0.6-V to 1.45-V range 12.5 mV
Output accuracy(1) 0.6 V to < 0.8 V –6% 6%
0.8 V to 1.45 V –4% 4%
Switching frequency 3.2 MHz
Conversion efficiency(2), Figure 5-2 in active mode IO = 10 mA, sleep 82%
100 mA < IO < 400 mA 85%
400 mA < IO < 600 mA 80%
600 mA < IO < 800 mA 75%
Output current Active mode 1.2 A
Sleep mode 10 mA
Ground current (IQ) Off at 30°C 3 μA
Sleep, unloaded 30 50
Active, unloaded, not switching 300
Short-circuit current VIN = VMax 2.2 A
Load regulation 0 < IO < IMax 20 mV
Transient load regulation(3) IO = 10 mA to (IMax/2) + 10 mA,
Maximum slew rate is IMax/2/100 ns
–65 50 mV
Line regulation 10 mV
Transient line regulation 300 mVPP ac input, 10-μs rise and fall time 10 mV
Start-up time 0.25 1 ms
Recovery time From sleep mode to on mode with constant load <10 100 μs
Slew rate (rising or falling)(4) 4 8 16 mV/μs
Output shunt resistor (pulldown) 500 700 Ω
External coil Value 0.7 1 1.3 μH
Data capture record (DCR) 0.1 Ω
Saturation current 1.8 A
External capacitor(5) Value 8 10 12 μF
Equivalent series resistance (ESR) at switching frequency 0 20
(1) Accuracy includes all variations (line and load regulations, line and load transients, temperature, and process)
(2) VBAT = 3.8 V, VDD1 = 1.3 V, Fs = 3.2 MHz, L = 1 μH, LDCR = 100 mΩ, C = 10 μF, ESR = 10 mΩ
(3) Output voltage must discharge the load current completely and settle to its final value within 100 μs.
(4) Load current varies proportionally with the output voltage. The slew rate is for increasing and decreasing voltages, and the maximum load current is 1.1 A.
(5) Under current load condition step:
Imax/2 (550 mA) in 100 ns with a ±20% external capacitor accuracy or
Imax/3 (367 mA) in 100 ns with a ±50% external capacitor accuracy

See Table 3-2 for how to connect the VDD1/2 DC-DC converter when it is not in use.

Figure 5-2 shows the efficiency of the VDD1 DC-DC regulator in active mode and sleep mode.

D001_SWCS037.gifFigure 5-2 VDD1 DC-DC Regulator Efficiency

5.1.1.1.2 External Components and Application Schematics

Figure 5-3 is an application schematic with the external components on the VDD1 DC-DC regulator.

swcs030-009.gifFigure 5-3 VDD1 DC-DC Application Schematic

NOTE

For the component values, see Table 5-48.

5.1.1.2 VDD2 DC-DC Regulator

5.1.1.2.1 VDD2 DC-DC Regulator Characteristics

The VDD2 DC-DC regulator is a programmable output stepdown DC-DC converter with an internal field effect transistor (FET). Like the VDD1 regulator, the VDD2 regulator can be placed in sleep or power-down mode and is SmartReflex-compatible. The VDD2 regulator differs from VDD1 in its current load capability. Table 5-4 describes the regulator characteristics.

Table 5-4 VDD2 DC-DC Regulator Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
Input voltage range 2.7 3.6 4.5 V
Output voltage 0.6 1 1.5 V
Output voltage step Covering the 0.6-V to 1.45-V range,
1.5 V is a single programmable value
12.5 mV
Output accuracy(1) 0.6 V to < 0.8 V –6% 6%
0.8 V to 1.5 V –4% 4%
Switching frequency 3.2 MHz
Conversion efficiency(2), Figure 5-4 in active mode IO = 10 mA, sleep 82%
100 mA < IO < 300 mA 85%
300 mA < IO < 500 mA 80%
Output current Active mode 600 mA
Sleep mode 10 mA
Ground current (IQ) Off at 30°C 1 μA
Sleep, unloaded 50
Active, unloaded, not switching 300
Short-circuit current VIN = VMax 1.2 A
Load regulation 0 < IO < IMax 20 mV
Transient load regulation(3) IO = 10 mA to (IMax/2) + 10 mA,
Maximum slew rate is IMax/2/100 ns
–65 50 mV
Line regulation 10 mV
Transient line regulation 300 mVPP ac input, 10-μs rise and fall time 10 mV
Output shunt resistor (internal pulldown) 500 700 Ω
Start-up time 0.25 1 ms
Recovery time From sleep mode to on mode with constant load 25 100 μs
Slew rate (rising or falling)(4) 4 8 16 mV/μs
External coil Value 0.7 1 1.3 μH
DCR 0.1 Ω
Saturation current 900 mA
External capacitor(5) Value 8 10 12 μF
ESR at switching frequency 0 20
(1) Accuracy includes all variations (line and load regulations, line and load transients, temperature, and process)
(2) VBAT = 3.8 V, VDD2 = 1.3 V, Fs = 3.2 MHz, L = 1 μH, LDCR = 100 mΩ, C = 10 μF, ESR = 10 mΩ
(3) Output voltage needs to discharge the load current completely and settle to its final value within 100 μs.
(4) Load current varies proportionally with the output voltage. The slew rate is for both increasing and decreasing voltages and the maximum load current is 600 mA.
(5) Under current load condition step:
Imax/2 (300 mA) in 100 ns with a ±20% external capacitor accuracy or
Imax/3 (200 mA) in 100 ns with a ±50% external capacitor accuracy

See Table 3-2 for how to connect the VDD1/2 DC-DC converter when it is not in use.

Figure 5-4 shows the efficiency of the VDD2 DC-DC regulator in active mode and sleep mode.

D002_SWCS037.gifFigure 5-4 VDD2 DC-DC Regulator Efficiency

5.1.1.2.2 External Components and Application Schematics

Figure 5-5 is an application schematic with the external components on the VDD2 DC-DC regulator.

swcs030-010.gifFigure 5-5 VDD2 DC-DC Application Schematic

NOTE

For the component values, see Table 5-48.

5.1.1.3 VIO DC-DC Regulator

5.1.1.3.1 VIO DC-DC Regulator Characteristics

The I/O and memory DC-DC regulator is a 600-mA stepdown DC-DC converter (internal FET) with two output voltage settings. It supplies the memories and all I/O ports in the application and is one of the first power providers to switch on in the power-up sequence. This DC-DC regulator can be placed in sleep or power-down mode; however, care must be taken in the sequencing of this power provider, because numerous ESD blocks are connected to this supply. Table 5-5 describes the regulator characteristics.

Table 5-5 VIO DC-DC Regulator Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
Input voltage range 2.7 3.6 4.5 V
Output voltage(1) 1.8
1.85
V
Output accuracy (2) –4% 4%
–3% 3%
Switching frequency 3.2 MHz
Conversion efficiency(3)Figure 5-6 in active mode IO = 10 mA, sleep 85%
100 mA < IO < 400 mA 85%
400 mA < IO < 600 mA 80%
Output current On mode 700 mA
Sleep mode 10
Ground current (IQ) Off at 30°C 1 μA
Sleep, unloaded 50
Active, unloaded, not switching 300
Load transient(4) 50 mV
Line transient 300 mVPP ac, input rise and fall time 10 μs 10 mV
Start-up time 0.25 1 ms
Recovery time From sleep mode to on mode with constant load <10 100 μs
Output shunt resistor (internal pulldown) 500 700 Ω
External coil Value 0.7 1 1.3 μH
DCR 0.1 Ω
Saturation current 900 mA
External capacitor Value 8 10 12 μF
ESR at switching frequency 1 20
(1) This voltage is tuned according to the platform and transient requirements.
(2) ±4% accuracy includes all the variation (line and load regulation, line and load transient, temperature, process)
±3% accuracy is dc accuracy only.
(3) VBAT = 3.8 V, VIO = 1.8 V, Fs = 3.2 MHz, L = 1 μH, LDCR = 100 mΩ, C = 10 μF, ESR = 10 mΩ
(4) Load transient can also be specified as 0 < IO < IOUTmax/2, Δt = 1 μs, 100 mV but this is not included in ±4% accuracy.

Figure 5-6 shows the efficiency of the VIO DC-DC regulator in active mode and sleep mode.

D003_SWCS037.gifFigure 5-6 VIO DC-DC Regulator Efficiency
Output Voltage = 1.2 V, VBAT = 3.8 V

5.1.1.3.2 External Components and Application Schematics

Figure 5-7 is an application schematic with the external components on the VIO DC-DC regulator.

swcs030-011.gifFigure 5-7 VIO DC-DC Application Schematic

NOTE

For the component values, see Table 5-48.

5.1.1.4 VDAC LDO Regulator

The VDAC programmable LDO regulator is a high-PSRR, low-noise linear regulator that powers the host processor dual-video DAC. It is controllable with registers through I2C and can be powered down. Table 5-6 describes the regulator characteristics.

Table 5-6 VDAC LDO Regulator Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VDAC.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
Electrical Characteristics
VIN Input voltage 2.7 3.6 4.5 V
VOUT Output voltage On mode 1.164 1.2 1.236 V
1.261 1.3 1.339
1.746 1.8 1.854
IOUT Rated output current On mode 70 mA
Low-power mode 5
dc load regulation On mode: 0 < IO < IMax 20 mV
dc line regulation On mode, VIN = VINmin to VINmax at IOUT = IOUTmax 3 mV
Turn-on time IOUT = 0, CL = 1 μF (within 10% of VOUT) 100 μs
Wake-up time Full load capability 10 μs
Ripple rejection f < 20 kHz 65 dB
20 kHz < f < 100 kHz 45
f = 1 MHz 40
VIN = VOUT + 1 V, IO = IMax
Output noise 100 Hz < f < 5 kHz 400 nV/√Hz
5 kHz < f < 400 kHz 125
400 kHz < f < 10 MHz 50
Ground current On mode, IOUT = 0 150 μA
On mode, IOUT = IOUTmax 350
Low-power mode, IOUT = 0 15
Low-power mode, IOUT = 1 mA 25
Off mode at 55°C 1
VDO Dropout voltage On mode, IOUT = IOUTmax 250 mV
Transient load regulation ILoad: IMin – IMax
Slew: 60 mA/μs
–40 40 mV
Transient line regulation VIN drops 500 mV
Slew: 40 mV/μs
10 mV

5.1.1.5 VPLL1 LDO Regulator

The VPLL1 programmable LDO regulator is a high-PSRR, low-noise, linear regulator used for the host processor PLL supply. Table 5-7 describes the regulator characteristics.

Table 5-7 VPLL1 LDO Regulator Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VPLL1.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
Electrical Characteristics
VIN Input voltage 2.7 3.6 4.5 V
VOUT Output voltage On mode and low-power mode 0.97 1.0 1.03 V
1.164 1.2 1.236
1.261 1.3 1.339
1.746 1.8 1.854
2.716 2.8 2.884
2.91 3.0 3.090
IOUT Rated output current On mode 40 mA
Low-power mode 5
dc load regulation On mode: 0 < IO < IMax 20 mV
dc line regulation On mode, VIN = VINmin to VINmax at IOUT = IOUTmax 3 mV
Turn-on time IOUT = 0, CL = 1 μF (within 10% of VOUT) 100 μs
Wake-up time Full load capability 10 μs
Ripple rejection f < 10 kHz 50 dB
10 kHz < f < 100 kHz 40
f = 1 MHz 30
VIN = VOUT + 1 V, IO = IMax
Ground current On mode, IOUT = 0 70 μA
On mode, IOUT = IOUTmax 110
Low-power mode, IOUT = 0 15
Low-power mode, IOUT = 1 mA 16
Off mode at 55°C 1
VDO Dropout voltage On mode, IOUT = IOUTmax 250 mV
Transient load regulation ILoad: IMin – IMax
Slew: 60 mA/μs
–40 40 mV
Transient line regulation VIN drops 500 mV
Slew: 40 mV/μs
10 mV

5.1.1.6 VMMC1 LDO Regulator

The VMMC1 LDO regulator is a programmable linear voltage converter that powers the multimedia card (MMC) slot. It includes a discharge resistor and overcurrent protection (short-circuit). This LDO regulator can also be turned off automatically when MMC card extraction is detected. The VMMC1 LDO can be powered through an independent supply other than the battery; for example, a charge pump. In this case, the input from the VMMC1 LDO can be higher than the battery voltage. Table 5-8 describes the regulator characteristics.

Table 5-8 VMMC1 LDO Regulator Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VMMC1.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
Electrical Characteristics
VIN Input voltage 2.7 3.6 5.5 V
VOUT Output voltage On mode and low-power mode 1.7945
2.7645
2.91
3.0555
1.85
2.85
3.0
3.15
1.9055
2.9355
3.09
3.2445
V
IOUT Rated output current On mode
Low-power mode
220
5
mA
dc load regulation On mode: 0 < IO < IMax 20 mV
dc line regulation On mode, VIN = VINmin to VINmax at IOUT = IOUTmax 3 mV
Turn-on time IOUT = 0, CL = 1 μF (within 10% of VOUT) 100 μs
Wake-up time Full load capability 10 μs
Ripple rejection f < 10 kHz
10 kHz < f < 100 kHz
f = 1 MHz
VIN = VOUT + 1 V, IO = IMax
50
40
25
dB
Ground current On mode, IOUT = 0
On mode, IOUT = IOUTmax
Low-power mode, IOUT = 0
Low-power mode, IOUT = 5 mA
Off mode at 55°C
70
290
17
20
1
μA
VDO Dropout voltage On mode, IOUT = IOUTmax 250 mV
Transient load regulation ILoad: IMin – IMax
Slew: 40 mA/μs
–40 40 mV
Transient line regulation VIN drops 500 mV
Slew: 40 mV/μs
10 mV

5.1.1.7 VAUX2 LDO Regulator

The VAUX2 general-purpose LDO regulator powers the auxiliary devices. Table 5-9 describes the regulator characteristics.

Table 5-9 VAUX2 LDO Regulator Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VAUX2.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
Electrical Characteristics
VIN Input voltage 2.7 3.6 4.5 V
VOUT Output voltage On mode and low-power mode –3% 1.3
1.5
1.7
1.8
1.9
2.0
2.1
2.2
2.3
2.4
2.5
2.8
3% V
IOUT Rated output current On mode
Low-power mode
100
5
mA
dc load regulation On mode: IOUT = IOUTmax to 0 20 mV
dc line regulation On mode, VIN = VINmin to VINmax at IOUT = IOUTmax 3 mV
Turn-on time IOUT = 0, CL = 1 μF (within 10% of VOUT) 100 μs
Wake-up time Full load capability 10 μs
Ripple rejection f < 10 kHz
10 kHz < f < 100 kHz
f = 1 MHz
VIN = VOUT + 1 V, IO = IMax
50
40
25
dB
Ground current On mode, IOUT = 0
On mode, IOUT = IOUTmax
Low-power mode, IOUT = 0
Low-power mode, IOUT = 5 mA
Off mode at 55°C
70
170
17
20
1
μA
VDO Dropout voltage On mode, IOUT = IOUTmax 250 mV
Transient load regulation ILoad: IMin – IMax
Slew: 40 mA/μs
–40 40 mV
Transient line regulation VIN drops 500 mV
Slew: 40 mV/μs
10 mV

5.1.1.8 Output Load Conditions

Table 5-10 lists the regulators that power the device, and the output loads associated with them.

Table 5-10 Output Load Conditions

REGULATOR PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
VINTDIG LDO Filtering capacitor Connected from VINTDIG.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
VINTANA1 LDO Filtering capacitor Connected from VINTANA1.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
VINTANA2 LDO Filtering capacitor Connected from VINTANA2.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
VRUSB_3V1 LDO Filtering capacitor Connected from VUSB.3P1 to GND 0.3 1 2.7 μF
Filtering capacitor ESR 0 10 600
VRUSB_1V8 LDO Filtering capacitor Connected from VINTUSB1P8.OUT to GND 0.3 1 2.7 μF
Filtering capacitor ESR 0 10 600
VRUSB_1V5 LDO Filtering capacitor Connected from VINTUSB1P5 to GND 0.3 1 2.7 μF
Filtering capacitor ESR 0 10 600

5.1.1.9 Charge Pump

The charge pump generates a 4.8-V (nominal) power supply voltage from the battery to the VBUS pin. The input voltage range is 2.7 to 4.5 V for the battery voltage. The charge pump operating frequency is 1 MHz.

The charge pump tolerates 7 V on VBUS when it is in power-down mode. The charge pump integrates a short-circuit current limitation at 450 mA. Table 5-11 lists the charge pump output load conditions.

Table 5-11 Charge Pump Output Load Conditions

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VBUS to VSSP 1.41 4.7 6.5 μF
Flying capacitor Connected from CP to CN 1.32 2.2 3.08 μF
Filtering capacitor ESR 20

5.1.1.10 USB LDO Short-Circuit Protection Scheme

The short-circuit current for the LDOs and DC-DCs in the TPS65920 and TPS65930 devices is approximately twice the maximum load current. When the output of the block is shorted to ground, the power dissipation can exceed the 1.2-W requirement if no action is taken. A short-circuit protection scheme is included in the TPS65920 and TPS65930 devices to ensure that if the output of an LDO or DC-DC is short-circuited, the power dissipation does not exceed the 1.2-W level.

The three USB LDOs, VRUSB3V1, VRUSB1V8, and VRUSB1V5, are included in this short-circuit protection scheme, which monitors the LDO output voltage at a frequency of 1 Hz and generates an interrupt (sc_it) when a short-circuit is detected.

The scheme compares the LDO output voltage to a reference voltage and detects a short-circuit if the LDO voltage drops below this reference value (0.5 or 0.75 V programmable). In the case of the VRUSB3V1 and VRUSB1V8 LDOs, the reference is compared with a divided down voltage (1.5 V typical).

If a short-circuit is detected on VRUSB3V1, the power subchip FSM switches this LDO to sleep mode.

If a short-circuit is detected on VRUSB1V8 or VRUSB1V5, the power subchip FSM switches off the relevant LDO.

5.1.2 Power References

The bandgap voltage reference is filtered (resistance/capacitance [RC] filter) using an external capacitor connected across the VREF output and an analog ground (REFGND). The VREF voltage is scaled, distributed, and buffered in the device. The bandgap is started in fast mode (not filtered), and is set automatically by the power state-machine in slow mode (filtered, less noisy) when required.

Table 5-12 lists the voltage reference characteristics.

Table 5-12 Voltage Reference Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Condition
Filtering capacitor Connected from VREF to GNDREF 0.3 1 2.7 μF
Electrical Characteristics
VIN Input voltage On mode 2.7 3.6 4.5 V
Internal bandgap reference voltage On mode, measured through TESTV terminal 1.272 1.285 1.298 V
Reference voltage (VREF terminal) On mode 0.749 0.75 0.77 V
Retention mode reference On mode 0.492 0.5 0.508 V
IREF NMOS sink 0.9 1 1.1 μA
Ground current Bandgap
IREF block
Preregulator
VREF buffer
Retention reference buffer
25
20
15
10
10
μA
Output spot noise 100 Hz 1 μV/√Hz
A-weighted noise (rms) 200 nV (rms)
P-weighted noise (rms) 150 nV (rms)
Integrated noise 20 to 100 kHz 2.2 μV
IBIAS trim bit LSB 0.1 μA
Ripple rejection <1 MHz from VBAT 60 dB
Start-up time 1 ms

5.1.3 Power Control

5.1.3.1 Backup Battery Charger

If the backup battery is rechargeable, it can be recharged from the main battery. A programmable voltage regulator powered by the main battery allows recharging of the backup battery. The backup battery charge must be enabled using a control bit register. Recharging starts when two conditions are met:

  • Main battery voltage > backup battery voltage
  • Main battery > 3.2 V

The comparators of the backup battery system (BBS) give the two thresholds of the backup battery charge startup. The programmed voltage for the charger gives the end-of-charge threshold. The programmed current for the charger gives the charge current.

Overcharging is prevented by measurement of the backup battery voltage through the GP ADC. Table 5-13 lists the characteristics of the backup battery charger.

Table 5-13 Backup Battery Charger Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
VBACKUP-to-MADC input attenuation VBACKUP from 1.8 to 3.3 V 0.33 V/V
Backup battery charging current VBACKUP = 2.8 V, BBCHEN = 1, BBISEL = 00 10 25 45 μA
VBACKUP = 2.8 V, BBCHEN = 1, BBISEL = 01 105 150 270 μA
VBACKUP = 2.8 V, BBCHEN = 1, BBISEL = 10 350 500 900 μA
VBACKUP = 2.8 V, BBCHEN = 1, BBISEL = 11 0.7 1 1.8 mA
VBACKUP = 0 V, BBCHEN = 1, BBISEL = 00 17.5 25 45 μA
VBACKUP = 0 V, BBCHEN = 1, BBISEL = 01 105 150 270 μA
VBACKUP = 0 V, BBCHEN = 1, BBISEL = 10 350 500 900 μA
VBACKUP = 0 V, BBCHEN = 1, BBISEL = 11 0.7 1 1.8 mA
End backup battery charging voltage: VBBCHGEND IVBACKUP = –10 μA, BBSEL = 00 2.4 2.5 2.6 V
IVBACKUP = –10 μA, BBSEL = 01 2.9 3.0 3.1 V
IVBACKUP = –10 μA, BBSEL = 10 3.0 3.1 3.2 V
IVBACKUP = –10 μA, BBSEL = 11 3.1 3.2 3.3 V

5.1.3.2 Battery Monitoring and Threshold Detection

5.1.3.2.1 Power On/Power Off and Backup Conditions

Table 5-14 lists the threshold levels of the battery.

Table 5-14 Battery Threshold Levels

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Main battery charged threshold VMBCH Measured on VBAT terminal 3.1 3.2 3.3 V
Main battery low threshold VMBLO VBACKUP = 3.2 V, measured on VBAT terminal (monitored on terminal ONNOFF) 2.55 2.7 2.85 V
Main battery high threshold VMBHI Measured on terminal VBAT, VBACKUP = 0 V
Measured on terminal VBAT, VBACKUP = 3.2 V
2.5
2.5
2.65
2.85
2.95
2.95
V
Batteries not present threshold VBNPR Measured on terminal VBACKUP with VBAT < 2.1 V
Measured on terminal VBAT with VBACKUP = 0 V
(monitored on terminal VRRTC)
1.6
1.95
1.8
2.1
2.0
2.25
V

5.1.3.3 VRRTC LDO Regulator

The VRRTC voltage regulator is a programmable, low dropout, linear voltage regulator supplying (1.5 V) the embedded real-time clock (32.768-kHz oscillator) and dedicated I/Os of the digital host counterpart. The VRRTC regulator is also the supply voltage of the power-management digital state-machine. The VRRTC regulator is supplied from the UPR line, switched on by the main or backup battery, depending on the system state. The VRRTC output is present as long as a valid energy source is present. The VRRTC line is supplied by an LDO when VBAT > 2.7, and a clamp circuit when in backup mode. Table 5-15 describes the regulator characteristics.

Table 5-15 VRRTC LDO Regulator Characteristics

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Output Load Conditions
Filtering capacitor Connected from VRTC.OUT to analog ground 0.3 1 2.7 μF
Filtering capacitor ESR 20 600
Electrical Characteristics
VIN Input voltage On mode 2.7 VBAT 4.5 V
VOUT Output voltage On mode 1.45 1.5 1.55 V
IOUT Rated output current On mode 30 mA
Sleep mode 1
DC load regulation On mode: IOUT = IOUTmax to 0 100 mV
DC line regulation On mode, VIN = VINmin to VINmax at IOUT = IOUTmax 100 mV
Turn-on time IOUT = 0, at VOUT = VOUTfinal ± 3% 100 μs
Wake-up time On mode from low power to On mode, IOUT = 0, at VOUT = VOUTfinal ± 3% 100 μs
From backup to On mode, IOUT = 0, at VOUT = VOUTfinal ± 3% 100
Ripple rejection (VRRTC) f < 10 kHz 50 dB
10 kHz < f < 100 kHz 40
f = 1 MHz 30
VIN = VOUT + 1 V, IO = IMAX
Ground current On mode, IOUT = 0 70 μA
On mode, IOUT = IOUTmax 100
Sleep mode, IOUT = 0 10
Sleep mode, IOUT = 1 mA 11
Off mode 1
VDO Dropout voltage(1) On mode, IOUT = IOUTmax 250 mV
Transient load regulation ILOAD: IMIN – IMAX
Slew: 40 mA/μs
–40 40 mV
Transient line regulation VIN drops 500 mV
Slew: 40 mV/μs
10 mV
Overshoot Softstart 3%
Pull down resistance Default in off mode 250 320 450 Ω
(1) For nominal output voltage

5.1.4 Power Consumption

Table 5-16 describes the power consumption depending on the use cases.

NOTE

Typical power consumption is obtained in the nominal operating conditions and with the TPS65920 and TPS65930 devices in stand-alone configuration.

Table 5-16 Power Consumption

MODE DESCRIPTION TYPICAL CONSUMPTION
Backup Only the RTC date is maintained with a couple of registers in the backup domain. No main source is connected. Consumption is on the backup battery. VBAT not present 2.25 * 3.2 = 7.2 μW
Wait on The phone is apparently off for the user, a main battery is present and well-charged. The RTC registers and registers in the backup domain are maintained. The wake-up capabilities (such as the PWRON button) are available. VBAT = 3.8 V 64 × 3.8 = 243.2 μW
Active no load The subsystem is powered by the main battery, all supplies are enabled with full current capability, internal reset is released, and the associated processor is running. VBAT = 3.8 V 3291 × 3.8 = 12505 μW
Sleep no load The main battery powers the subsystem, selected supplies are enabled but in low-consumption mode, and the associated processor is in low-power mode. VBAT = 3.8 V 496 × 3.8 = 1884.4 μW

Table 5-17 lists the regulator states according to the mode in use.

Table 5-17 Regulator State Depending on Use Case

REGULATOR MODE
BACKUP WAIT ON SLEEP NO LOAD ACTIVE NO LOAD
VAUX2 OFF OFF SLEEP ON
VMMC1 OFF OFF OFF OFF
VPLL1 OFF OFF SLEEP ON
VDAC OFF OFF OFF OFF
VINTANA1 OFF OFF SLEEP ON
VINTANA2 OFF OFF SLEEP ON
VINTDIG OFF OFF SLEEP ON
VIO OFF OFF SLEEP ON
VDD1 OFF OFF SLEEP ON
VDD2 OFF OFF SLEEP ON
VUSB_1V5 OFF OFF OFF OFF
VUSB_1V8 OFF OFF OFF OFF
VUSB_3V1 OFF OFF SLEEP SLEEP

5.1.5 Power Management

5.1.5.1 Boot Modes

Table 5-18 lists the modes corresponding to BOOT0–BOOT1.

Table 5-18 BOOT Mode Description

NAME DESCRIPTION BOOT0 BOOT1
Reserved 0 0
MC027 Master_C027_Generic 01 0 1
MC021 Master_C021_Generic 10 1 0
SC021 Slave_C021_Generic 11 1 1

5.1.5.2 Process Modes

This parameter defines:

  • The boot voltage for the host core
  • The boot sequence associated with the process
  • The dynamic voltage and frequency scaling (DVFS) protocol associated with the process

5.1.5.2.1 MC021 Mode

Table 5-19 lists the characteristics of MC021 mode.

Table 5-19 MC021 Mode

Boot core voltage 1.2 V
Power sequence VIO followed by VPLL1, VDD2, VDD1
DVFS protocol SmartReflex IF (I2C HS)

5.1.5.3 Power-On Sequence

5.1.5.3.1 Timing Before Sequence_Start

Sequence_Start is a symbolic internal signal to ease the description of the power sequences. It occurs according to the events shown in Figure 5-8.

swcs030-012.gifFigure 5-8 Timing Before Sequence Start

5.1.5.3.2 Power-On Sequence

Figure 5-9 describes the timing and control that must occur in the OMAP3 mode. Sequence_Start is a symbolic internal signal to ease the description of the power sequences. It occurs according to the events shown in Figure 5-8.

SWCS019-072.gifFigure 5-9 Timings–Power On in OMAP3 Mode

5.1.5.3.3 Power On in Slave_C021 Mode

Figure 5-10 describes the timing and control that must occur in the Slave_C021 mode. Sequence_Start is a symbolic internal signal to ease the description of the power sequences and occurs according to the different events detailed in Figure 5-8.

swcs030-022.gifFigure 5-10 Timings—Power On in Slave_C021 Mode

5.1.5.4 Power-Off Sequence

This section describes the signal behavior required to power down the system.

5.1.5.4.1 Power-Off Sequence

Figure 5-11 shows the timing and control that occur during the power-off sequence in master modes.

swcs037-055.gif

NOTE:

All of these timings are typical values with the default setup (depending on the resynchronization between power domains, state machinery priority, etc.).
Figure 5-11 Power-Off Sequence in Master Modes

Because of the internal frequency used by Power STM switching from 3 to 1.5 MHz when the HF clock value is 19.2 MHz, if the HF clock value is not 19.2 MHz (with HFCLK_FREQ bit field values set accordingly in the CFG_BOOT register), the delay between DEVOFF and NRESPWRON/CLK32KOUT/SYSEN/HFCLKOUT is divided by two (approximately 9 μs).

The DEVOFF event is PWRON falling edge in slave mode and DEVOFF internal register write in master mode.

5.2 Real-Time Clock and Embedded Power Controller

The TPS65930 and TPS65920 devices contain an RTC to provide clock and timekeeping functions and an EPC to provide battery supervision and control.

5.2.1 RTC

The RTC provides the following basic functions:

  • Time information (seconds/minutes/hours) directly in binary-coded decimal (BCD) code
  • Calendar information (day/month/year/day of the week) directly in BCD code
  • Interrupt generation periodically (1 second/1 minute/1 hour/1 day) or at a precise time (alarm function)
  • 32-kHz oscillator drift compensation and time correction
  • Alarm-triggered system wake-up event

5.2.1.1 Backup Battery

The TPS65030 and TPS65920 devicesdevice implement a backup mode in which a backup battery can keep the RTC running to maintain clock and time information even if the main supply is not present. If the backup battery is rechargeable, the device also provides a backup battery charger so it can be recharged when the main battery supply is present.

The backup domain powers the following:

  • Internal 32.768-kHz crystal oscillator
  • RTC
  • Eight general-purpose (GP) storage registers
  • Backup domain low-power regulator (VBRTC)

5.2.2 EPC

The EPC provides five system states for optimal power use by the system, as listed in Table 5-20.

Table 5-20 System States

SYSTEM STATE DESCRIPTION
NO SUPPLY The system is not powered by any battery.
BACKUP The system is powered only with the backup battery and maintains only the VBRTC supply.
WAIT-ON The system is powered by the main battery and maintains only the VRRTC supply. It can accept switch-on requests.
ACTIVE The system is powered by the main battery; all supplies can be enabled with full current capability.
SLEEP The main battery powers the system; selected supplies are enabled, but in low consumption mode.

Three categories of events can trigger state transitions:

  • Hardware events: Supply/battery insertion, wake-up requests, USB plug, and RTC alarm
  • Software events: Switch-off commands, switch-on commands, and sleep on commands
  • Monitoring events: Supply/battery level check, main battery removal, main battery fail, and thermal shutdown

5.3 USB Transceiver

The TPS65920/TPS65930 device includes a USB OTG transceiver with the CEA carkit interface that supports USB 480 Mbps HS, 12 Mbps full-speed (FS), and USB 1.5 Mbps low-speed (LS) through a 4-pin ULPI.

The carkit block ensures the interface between the phone and a carkit device. The TPS65920/TPS65930 USB supports the CEA carkit standard.

Figure 5-12 is a block diagram of the USB 2.0 physical layer (PHY).

swcs037-011.gifFigure 5-12 USB 2.0 PHY Block Diagram

5.3.1 Features

The device has a USB OTG carkit transceiver that allows system implementation that complies with the following specifications:

  • Universal Serial Bus 2.0 Specification
  • On-The-Go Supplement to the USB 2.0 Specification
  • CEA-2011: OTG Transceiver Interface Specification
  • CEA-936A: Mini-USB Analog Carkit Specification
  • UTMI+ Low Pin Interface Specification

The features of the individual specifications are:

  • Universal Serial Bus 2.0 Specification (hereafter referred to as the USB 2.0 specification):
    • 5-V-tolerant data line at HS/FS, FS-only, and LS-only transmission rates
    • 7-V-tolerant video bus (VBUS) line
    • Integrated data line serial termination resistors (factory-trimmed)
    • Integrated data line pullup and pulldown resistors
    • On-chip 480-MHz phase-locked loop (PLL) from the internal system clock (19.2, 26, and 38.4 MHz)
    • Synchronization (SYNC)/end-of-period (EOP) generation and checking
    • Data and clock recovery from the USB stream
    • Bit-stuffing/unstuffing and error detection
    • Resume signaling, wakeup, and suspend detection
    • USB 2.0 test modes
  • On-The-Go Supplement to the USB 2.0 Specification (hereafter referred to as the OTG supplement to the USB 2.0 specification):
    • 3-pin LS/FS serial mode (DAT_SE0)
    • 4-pin LS/FS serial mode (VP_VM)
  • CEA-936A: Mini-USB Analog Carkit Interface Specification:
    • 5-pin CEA mini-USB analog carkit interface
    • UART signaling
    • Audio (mono/stereo) signaling
    • UART transactions during audio signaling
    • Basic and smart 4-wire/5-wire carkit, chargers, and accessories
    • ID CEA resistor comparators
  • UTMI+ Low Pin Interface Specification (hereafter referred to as the ULPI specification):
    • 12-pin ULPI with 8-pin parallel data for USB signaling and register access
    • 60-MHz clock generation
    • Register mapping

Figure 5-13 is the USB system application schematic.

swcs037-012.gifFigure 5-13 USB System Application Schematic

NOTE

For the component values, see Table 5-48.

5.3.2 HS USB Port Timing

The ULPI interface supports an 8-bit data bus and the internal clock mode. The 4-bit data bus and the external clock mode are not supported.

The HS functional mode supports an operating rate of 480 Mbps.

Table 5-21 and Table 5-22 assume testing over the recommended operating conditions (see Figure 5-14).

swcs037-049.gifFigure 5-14 HS-USB Interface—Transmit and Receive Modes (ULPI 8-bit)

NOTE

ULPI data [7:0] lines are set to 1 after USB PHY power up, and before the clock signal is stable.

The input timing requirements are given by considering a rising or falling time of 1 ns (see Table 5-21).

Table 5-21 HS-USB Interface Timing Requirements

NOTATION PARAMETER MIN MAX UNIT
HSU4 ts(STPV-CLKH) Setup time, STP valid before UCLK rising edge 6 ns
HSU5 th(CLKH-STPIV) Hold time, STP valid after UCLK rising edge 0 ns
HSU6 ts(DATAV-CLKH) Setup time, DATA[0:7] valid before UCLK rising edge 6 ns
HSU7 th(CLKH-DATIV) Hold time, DATA[0:7] valid after UCLK rising edge 0 ns

Table 5-22 lists the HS-USB interface switching requirements.

Table 5-22 HS-USB Interface Switching Requirements(1)

NOTATION PARAMETER(1) MIN TYP MAX UNIT
HSU0 fp(CLK) UCLK clock frequency Steady state 58.42 60 61.67 MHz
HSU1 tW(CLK) UCLK duty cycle Steady state 48.3% 50% 51.7%
HSU2 td(CLKH-DIR) Delay time, UCLK rising edge to DIR transition Steady state 0 9 ns
td(CLKH-NXTV) Delay time, UCLK rising edge to NXT transition Steady state 0 9 ns
HSU3 td(CLKH-DATV) Delay time, UCLK rising edge to DATA[0:7] transition Steady state 0 9 ns
(1) The capacitive load for output data and control load is 10 pF (rising and falling time is 2 ns).
The capacitive load for the CLK port is 6 pF (rising and falling time is 1 ns).
The HS-USB interface has only one state: the steady state.

5.3.3 USB-CEA Carkit Port Timing

This mode allows the link for communication through the USB PHY to a remote carkit in CEA audio + data during audio (DDA) mode as defined in the CEA-936A specification. In this mode, the ULPI data bus is redefined as a 2-pin UART interface, which exchanges data through a direct access to the FS/LS analog transmitter and receiver.

UART data are sent and received on the USB D+/D– pads. D+/D– are also used in this mode to carry audio I/O signals.

Table 5-23 assumes testing over the recommended operating conditions (see the CEA-936A specification).

Table 5-23 USB-CEA Carkit Interface Timing Parameters

PARAMETER MIN MAX UNIT
tPH_DP_CON Phone D+ connect time 100 ms
tCR_DP_CON Carkit D+ connect time 150 300 ms
tPH_DM_CON Phone D– connect time 10 ms
tPH_CMD_DLY Phone command delay 2 ms
tPH_MONO_ACK Phone mono acknowledge 10 ms
tPH_DISC_DET Phone D+ disconnect time 150 ms
tCR_DISC_DET Carkit D– disconnect detect 50 150 ms
tPH_AUD_BIAS Phone audio bias 1 ms
tCR_AUD_DET Carkit audio detect 400 800 μs
tCR_UART_DET Carkit UART detect (data-during-audio enabled) 700 1200 ns
tPH_STLO_DET Phone stereo D+ low detect 30 100 ms
tPH_PLS_POS Phone D– interrupt pulse width 200 600 ns
tCR_PLS_NEG Carkit D+ interrupt pulse width 200 600 ns
tDAT_AUD_POL Data-during-audio polarity 20 60 ms
tACC_COL_DET Accessory ID collision detect 2 3 ms
tACC_INT_PW Accessory ID interrupt pulse width 200 400 μs
tACC_INT_WAIT Accessory ID interrupt wait time 10 15 ms
tACC_CMD_WAIT Accessory ID command wait time 0 ms
tPH_INT_PW Phone ID interrupt pulse width 4 8 ms
tPH_INT_WAIT Phone ID interrupt wait time 4 8 ms
tPH_CMD_WAIT Phone ID command wait time 0 ms
tPH_UART_RPT Phone command repeat time 50 ms
tCR_UART_RSP Carkit UART response 30 ms
tCR_INT_RPT Carkit interrupt repeat time 50 ms
fUART_DFLT Default UART signaling rate (typical rate) 9600 bps

Figure 5-15 shows the USB-CEA carkit UART data flow.

swcs037-048.gifFigure 5-15 USB-CEA Carkit UART Data Flow

Table 5-24 lists the USB-CEA carkit UART timings.

Table 5-24 USB-CEA Carkit UART Timings

NOTATION PARAMETER MIN MAX UNIT
CK1 td(UART_TXH-DM) Delay time, UART_TX rising edge to DM transition 4.0 11 ns
CK2 td(UART_TXL-DM) Delay time, UART_TX falling edge to DM transition 4.0 11 ns
CK3 td(DPH-UART_RX) Delay time, DP rising edge to UART_RX transition At 38.4 MHz 205 234 ns
At 19.2 MHz 310 364
CK4 td(DPL-UART_RX) Delay time, DP falling edge to UART_RX transition At 38.4 MHz 205 234 ns
At 19.2 MHz 310 364

Figure 5-16 shows the USB-CEA carkit UART timings.

swcs037-047.gifFigure 5-16 USB-CEA Carkit UART Timings

5.3.4 PHY Electrical Characteristics

The PHY is the physical signaling layer of the USB 2.0. It contains the drivers and receivers for physical data and protocol signaling on the DP and DM lines.

The PHY interfaces with the USB controller through the UTMI.

The transmitters and receivers in the PHY are of two main classes:

  • FS and LS transceivers (legacy USB1.x transceivers)
  • HS transceivers

To bias the transistors and run the logic, the PHY also contains reference generation circuitry which consists of:

  • A DPLL that does a frequency multiplication to achieve the 480-MHz low-jitter lock necessary for USB, and the clock required for the switched capacitor resistance block
  • A switched capacitor resistance block that replicates an external resistor on chip

Built-in pullup and pulldown resistors are used as part of the protocol signaling.

The PHY also contains circuitry that protects it from an accidental 5-V short on the DP and DM lines and from 8-kV IEC ESD strikes.

5.3.4.1 HS Differential Receiver

The HS receiver consists of the following blocks:

  • A differential input comparator to receive the serial data
  • A squelch detector to qualify the received data
  • An oversampler-based clock data recovery scheme followed by a nonreturn to zero inverted (NRZI) decoder, bit unstuffing, and serial-to-parallel converter to generate the UTMI DATAOUT

Table 5-25 lists the characteristics of the HS differential receiver.

Table 5-25 HS Differential Receiver

PARAMETER COMMENTS MIN TYP MAX UNIT
Input Levels for HS
HS squelch detection threshold VHSSQ (Differential signal amplitude) 100 125 150 mV
HS disconnect detection threshold VHSDSC (Differential signal amplitude) 525 600 625 mV
HS data signaling common mode voltage range VHSCM –50 200 500 mV
HS differential input sensitivity VDIHS (Differential signal amplitude) –100 100 mV
Input Impedance for HS
Internal specification for input capacitance CHSLOAD 11 pF
Internal CHSLOAD DP/DM matching CHSLOADM 0.2 pF
External Components With the Total Budget Combined (without USB cable load)
External capacitance on DP or DM 2 pF
External series resistance on DP or DM 1 Ω

5.3.4.2 HS Differential Transmitter

The HS transmitter is always operated on the UTMI parallel interface. The parallel data on the interface is serialized, bit stuffed, NRZI encoded, and transmitted as a dc output current on DP or DM, depending on the data. Each line has an effective 22.5-Ω load to ground, which generates the voltage levels for signaling.

A disconnect detector is also part of the HS transmitter. A disconnect on the far end of the cable causes the impedance seen by the transmitter to double, thereby doubling the differential amplitude seen on the DP/DM lines.

Table 5-26 lists the characteristics of the HS differential transmitter.

Table 5-26 HS Differential Transmitter

PARAMETER COMMENTS MIN TYP MAX UNIT
Output Levels for HS
HS TX idle level VHSOI Absolute voltage DP/DM – internal/external 45 Ω –10 0 10 mV
HS TX data signaling high VHSOH Absolute voltage DP/DM – internal/external 45 Ω 360 400 440 mV
HS data signaling low VHSOL –10 0 10 mV
Chirp J level VCHIRPJ Differential voltage 700 800 1100 mV
Chirp K level VCHIRPK Differential voltage –900 –800 –500 mV
HS TX disconnect threshold VDISCOUT Absolute voltage DP/DM – no external 45 Ω 700 mV
Driver Characteristics
Rise time tHSR (10%–90%) 500 ps
Fall time tHSF (10%–90%) 500 ps
Driver output resistance ZHSDRV Also serves as HS termination 40.5 45 49.5 Ω

5.3.4.3 CEA/UART Driver

Table 5-27 lists the characteristics of the CEA/UART driver.

Table 5-27 CEA/UART Driver

PARAMETER COMMENTS MIN TYP MAX UNIT
UART Driver CEA
Phone UART edge rates tPH_UART_EDGE DP_PULLDOWN asserted 1 μs
Serial interface output high VOH_SER ISOURCE = 4 mA 2.4 3.3 3.6 V
Serial interface output low VOL_SER ISINK = –4 mA 0 0.1 0.4 V
Carkit Pulse Driver
Pulse match tolerance QPLS_MTCH ZCR_SPKR_IN = 60 kΩ at f = 1 kHz 5%
Phone D– interrupt pulse width tPH_PLS_POS ZCR_SPKR_IN = 60 kΩ at f = 1 kHz 200 600 ns
Phone positive pulse voltage VPH_PLS_POS ZCR_SPKR_IN = 60 kΩ at f = 1 kHz 2.8 3.6 V

5.3.4.4 Pullup/Pulldown Resistors

Table 5-28 lists the characteristics of pullup/pulldown resistors.

Table 5-28 Pullup/Pulldown Resistors

PARAMETER COMMENTS MIN TYP MAX UNIT
Pullup Resistors
Bus pullup resistor on upstream port (idle bus) RPUI Bus idle 0.9 1.1 1.575
Bus pullup resistor on upstream port (receiving) RPUA Bus driven/driver outputs unloaded 1.425 2.2 3.09
High (floating) VIHZ Pullups/pulldowns on DP and DM lines 2.7 3.6 V
Phone D+ pullup voltage VPH_DP_UP Driver outputs unloaded 3 3.3 3.6 V
Pulldown Resistors
Phone D+/– pulldown RPH_DP_DWN Driver outputs unloaded 14.25 18 24.8
RPH_DM_DWN
High (floating) VIHZ Pullups/pulldowns on DP and DM lines 2.7 3.6 V
D+/– Data Line
Upstream facing port CINUB [1.0] 22 75 pF
OTG device leakage VOTG_DATA_LKG [2] 0.342 V
Input impedance exclusive of pullup/pulldown(1) ZINP Driver outputs unloaded (waiver from USB.ORG Standard Committee) 80 120
(1) Waiver received from usb.org standards committee on ZINP 300kmin specification

5.3.5 OTG Electrical Characteristics

The OTG block integrates three main functions:

  • The USB plug detection function on VBUS and ID
  • The ID resistor detection
  • The VBUS level detection

5.3.5.1 OTG VBUS Electrical Characteristics

Table 5-29 lists the electrical characteristics of the OTG VBUS.

Table 5-29 OTG VBUS Electrical Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
VBUS Wake-Up Comparator
VBUS wake-up delay DELVBUS_WK_UP 15 μs
VBUS wake-up threshold VVBUS_WK_UP 0.5 0.6 0.7 V
VBUS Comparators
A-device session valid VA_SESS_VLD 0.8 1.1 1.4 V
A-device VBUS valid VA_VBUS_VLD 4.4 4.5 4.6 V
B-device session end VB_SESS_END 0.2 0.5 0.8 V
B-device session valid VB_SESS_VLD 2.1 2.4 2.7 V
VBUS Line
A-device VBUS input impedance to ground RA_BUS_IN SRP (VBUS pulsing) capable A-device not driving VBUS 100
B-device VBUS SRP pulldown RB_SRP_DWN 5.25 V/8 mA, pullup voltage = 3 V 0.656 10
B-device VBUS SRP pullup RB_SRP_UP (5.25 V – 3 V)/8 mA, pullup voltage = 3 V 0.281 1 2
B-device VBUS SRP rise time maximum for OTG-A communication tRISE_SRP_UP_Max 0 to 2.1 V with < 13 μF load 36 ms
B-device VBUS SRP rise time minimum for standard host connection tRISE_SRP_UP_Min 0.8 to 2.0 V with > 97 μF load 60 ms
VBUS line maximum voltage If VBUS_CHRG bit is low 7 V

5.3.5.2 OTG ID Electrical Characteristics

Table 5-30 lists the electrical characteristics of OTG ID.

Table 5-30 OTG ID Electrical Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
ID Wake-Up Comparator
ID wake-up comparator RID_WK_UP Wake-up when ID shorted to ground through a resistor lower than 445 kΩ (±1%) 445
ID Comparators — ID External Resistor Specifications
ID ground comparator RID_GND ID_GND interrupt when ID shorted to ground through a resistor lower than 10 Ω 0 5 10 Ω
ID 100k comparators RID_100K ID_100K interrupt when 102 kΩ (1%) resistor plugged in 101 102 103
ID 200k comparators RID_200K ID_200K interrupt when 200 kΩ (1%) resistor plugged in 198 200 202
ID 440k comparators RID_440K ID_440K interrupt when 440 kΩ (1%) resistor plugged in 435 440 445
ID Float comparator RID_FLOAT ID_FLOAT interrupt when ID shorted to ground through a resistor higher than 560 kΩ 1400
ID Line
Phone ID pullup to VPH_ID_UP RPH_ID_UP ID unloaded (VRUSB) 70 200 286
Phone ID pullup voltage VPH_ID_UP Connected to VRUSB 2.5 3.2 V
ID line maximum voltage 5.25 V

5.4 MADC

5.4.1 General Description

The TPS65920/TPS65930 device provides the MADC resource to the host processors in the system (hardware and software conversion modes).

The MADC generates interrupt signals to the host processors. Interrupts are handled primarily by the MADC internal secondary interrupt handler and secondly at the upper level (outside the MADC) by the TPS65920/TPS65930 interrupt primary handler.

5.4.2 MADC Electrical Characteristics

Table 5-31 lists the electrical characteristics of the MADC.

Table 5-31 MADC Electrical Characteristics

PARAMETER CONDITIONS MIN TYP MAX UNIT
Resolution 10 Bit
ADIN2 input dynamic range for external input 0 2.5 V
MADC voltage reference 1.5 V
ADIN0 differential nonlinearity –1 1 LSB
ADIN0 integral nonlinearity Best fitting –2 2 LSB
Integral nonlinearity for ADIN2 Best fitting for codes 230 to maximum –2 2 LSB
Best fitting considering offset of 25 LSB –3.75 3.75 LSB
Offset Best fitting –28.5 28.5 mV
Input bias 1 μA
Input capacitor CBANK 10 pF
Maximum source input resistance Rs (for all 16 internal or external inputs) 100
Input current leakage (for all 16 internal or external inputs) 1 μA

5.4.3 Channel Voltage Input Range

Table 5-32 lists the analog input voltage minimum and maximum values.

Table 5-32 Analog Input Voltage Range

CHANNEL MIN TYP MAX UNIT PRESCALER
ADIN0: General-purpose input 0 1.5 V No prescaler
DC current source for battery identification through external resistor (10 μA typical)
ADIN2: General-purpose input(1) 0 2.5 V Prescaler in the MADC to be in range 0 to >1.5 V
(1) General-purpose inputs must be tied to ground when TPS65920/TPS65930 internal power supplies (VINTANA1 and VINTANA2) are off.

5.4.3.1 Sequence Conversion Time (Real-Time or Nonaborted Asynchronous)

Table 5-33 lists the sequence conversion timing characteristics.

Table 5-33 Sequence Conversion Timing Characteristics

PARAMETER COMMENTS MIN TYP MAX UNIT
F Running frequency 1 MHz
T = 1/F Clock period 1 μs
N Number of analog inputs to convert in a single sequence 0 2
Tstart SW1, SW2, or USB asynchronous request or real-time STARTADC request 3 4 μs
Tsettling time Settling time to wait before sampling a stable analog input (capacitor bank charge time) 5 12 20 μs
Tsettling is calculated from the max((Rs + Ron)*Cbank) of the two possible input sources (internal or external). Ron is the resistance of the selection analog input switches (5 kΩ). This time is software-programmable by the open-core protocol (OCP) register.
Tstartsar The successive approximation registers ADC start time 1 μs
Tadc time The successive approximation registers ADC conversion time 10 μs
Tcapture time Tcapture time is the conversion result capture time. 2 μs
Tstop 1 2 μs
Full-conversion sequence time One channel (N = 1)(1) 22 39 μs
Both channels(1) 352 624
Conversion sequence time Without Tstart and Tstop: One channel (N = 1)(1) 18 33 μs
Without Tstart and Tstop: Both channels(1) 288 528
STARTADC pulse duration STARTADC period is T. 0.33 24 μs
(1) Total sequence conversion time general formula: Tstart+N*(1+Tsettling+Tadc+Tcapture) +Tstop

Table 5-33 is illustrated in Figure 5-17, which is a conversion sequence general timing diagram. The Busy parameter indicates that a conversion sequence is running, and the channel N result register parameter corresponds to the result register of the RT/GP selected channel.

swcs037-046.gifFigure 5-17 Conversion Sequence General Timing Diagram

5.5 LED Drivers

5.5.1 General Description

Two arrays of parallel LEDs are driven (dedicated for the phone light). The parallel LEDs are supplied by VBAT, and the external resistor value is given for each LED. The TPS65920/TPS65930 device supports two open-drain LED drivers for the keypad backlight, having drain connections tolerant of the main battery voltage.

Figure 5-18 is the LED driver block diagram. Table 5-34 lists the electrical characteristics of the LED driver.

swcs037-045.gifFigure 5-18 LED Driver Block Diagram

NOTE

For the component values, see Table 5-48.

Table 5-34 LED Driver Electrical Characteristics

PARAMETER CONDITIONS MIN TYP MAX UNIT
SW On resistance IO = 160 mA 3 4 Ω
IO = 60 mA 10 12

5.6 Keyboard

5.6.1 Keyboard Connection

The keyboard is connected to the chip using:

  • KBR (5 :0) input pins for row lines
  • KBC (5 :0) output pins for column lines

Figure 5-19 shows the keyboard connection.

swcs037-014.gifFigure 5-19 Keyboard Connection

When a key button of the keyboard matrix is pressed, the corresponding row and column lines are shorted together. To allow key press detection, all input pins (KBR) are pulled up to VCC and all output pins (KBC) are driven to a low level.

Any action on a button generates an interrupt to the sequencer.

The decoding sequence is written to allow detection of simultaneous press actions on several key buttons.

The keyboard interface can be used with a smaller keyboard area than 6 × 6. To use a 3 × 3 keyboard, KBR(4) and KBR(5) must be tied high to prevent any scanning process distribution.

5.7 Clock Specifications

The TPS65920/TPS65930 device includes several I/O clock pins. The TPS65920/TPS65930 device has two sources of high-stability clock signals: the external high-frequency clock (HFCLKIN) input and an onboard 32-kHz oscillator (an external 32-kHz signal can be provided). Figure 5-20 is the clock overview.

swcs030-002.gifFigure 5-20 Clock Overview

5.7.1 Clock Features

The TPS65920/TPS65930 device accepts two sources of high-stability clock signals:

  • 32KXIN/32KXOUT: Onboard 32-kHz crystal oscillator (an external 32-kHz input clock can be provided)
  • HFCLKIN: External high-frequency clock (19.2, 26, or 38.4 MHz).

The TPS65920/TPS65930 device can provide:

  • 32KCLKOUT digital output clock
  • HFCLKOUT digital output clock with the same frequency as the HFCLKIN input clock

5.7.2 Input Clock Specifications

The clock system accepts two input clock sources:

  • 32-kHz crystal oscillator clock or sinusoidal/squared clock
  • HFCLKIN high-frequency input clock

5.7.2.1 Clock Source Requirements

Table 5-35 lists the input clock requirements.

Table 5-35 TPS65920/TPS65930 Input Clock Source Requirements

PAD CLOCK FREQUENCY STABILITY DUTY CYCLE
32KXIN
32KXOUT
32.768 kHz Crystal ±30 ppm 40%/60%
Square wave 45%/55%
Sine wave
HFCLKIN 19.2, 26, 38.4 MHz Square wave ±150 PPM See (1)
Sine wave
(1) HFCLK duty cycle and frequency is not altered by the internal circuit. The input clock accuracy must match that of the system requirement; for example, OMAP device.

5.7.2.2 HFCLKIN

HFCLKIN can be a square- or a sine-wave input clock. If a square-wave input clock is provided, it is recommended to switch the block to bypass mode to avoid loading the clock.

Figure 5-21 shows the HFCLKIN clock distribution.

swcs037-044.gifFigure 5-21 HFCLKIN Clock Distribution

When a device needs a clock signal other than 32.768 kHz, it makes a clock request and activates the CLKREQ pin. As a result, the TPS65920/TPS65930 device immediately sets CLKEN to 1 to warn the clock provider in the system about the clock request and starts a timer (maximum of 5.2 ms using the 32.768-kHz clock). When the timer expires, the TPS65920/TPS65930 device opens a gated clock, the timer automatically reloads the defined value, and a high-frequency output clock signal is available through the HFCLKOUT pin. The output drive of HFCLKOUT is programmable (minimum load 10 pF, maximum load 40 pF) and must be at 40 pF by default.

With a register setting, the mirroring of CLKEN can be enabled on CLKEN2. When this mirroring feature is not enabled, CLKEN2 can be used as a general-purpose output controlled through I2C accesses.

CLKREQ, when enabled, has a weak pulldown resistor to support the wired-OR clock request.

Figure 5-22 shows an example of the wired-OR clock request.

swcs037-043.gifFigure 5-22 Example of Wired-OR Clock Request

The timer default value must be the worst case (10 ms) for the clock providers. For legacy or workaround support, the NSLEEP1 and NSLEEP2 signals can also be used as a clock request even if it is not their primary goal. By default, this feature is disabled and must be enabled individually by setting the register bits associated with each signal.

When the external clock signal is present on the HFCLKIN ball, it is possible to use this clock instead of the internal RC oscillator and then synchronize the system on the same clock. The RC oscillator can then go to idle mode.

Table 5-36 lists the input clock electrical characteristics of the HFCLKIN input clock.

Table 5-36 HFCLKIN Input Clock Electrical Characteristics

PARAMETER DESCRIPTION CONFIGURATION MODE SLICER MIN TYP MAX UNIT
Frequency 19.2, 26, or 38.4 MHz
Start-up time LP(1)/HP(2) (sine wave) 4 μs
Input dynamic range LP/HP (sine wave) 0.3 0.7 1.45 VPP
BP(3)/PD(4) (square wave) 0 1.85(5)
Current consumption LP 175 μA
HP 235
BP/PD 39 nA
Harmonic content of input signal (with 0.7-VPP amplitude): second component LP/HP (sine wave) –25 dBc
VIH Voltage input high BP (square wave) 1 V
VIL Voltage input low BP (square wave) 0.6 V
(1) LP = Low-power mode
(2) HP = High-power mode
(3) BP = Bypass mode
(4) PD = Power-down mode
(5) Bypass input max voltage is the same as the maximum voltage provided for the I/O interface (IO.1P8V).

Table 5-37 lists the input clock timing requirements of the HFCLKIN input clock when the source is a square wave. Figure 5-23 shows the HFCLKIN squared input clock timings.

Table 5-37 HFCLKIN Square Input Clock Timing Requirements with Slicer in Bypass

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
CH0 1/tC(HFCLKIN) Frequency, HFCLKIN 19.2, 26, or 38.4 MHz
CH1 tW(HFCLKIN) Pulse duration, HFCLKIN low or high 0.45*tC(HFCLKIN) 0.55*tC(HFCLKIN) ns
CH3 tR(HFCLKIN) Rise time, HFCLKIN(1) 5 ns
CH4 tF(HFCLKIN) Fall time, HFCLKIN(1) 5 ns
(1) Default drive capability is 40 pF.
SWCS019-017.gifFigure 5-23 HFCLKIN Squared Input Clock

5.7.2.3 32-kHz Input Clock

A 32.768-kHz input clock (often abbreviated to 32-kHz) generates the clocks for the RTC. It has a low-jitter mode where the current consumption increases for lower jitter. It is possible to use the 32-kHz input clock with an external crystal or clock source. Depending on the mode chosen, the 32K oscillator is configured one of two ways:

  • An external 32.768-kHz crystal through the 32KXIN/32KXOUT balls (see Figure 5-24). This configuration is available only for master mode (for more information, see Section 4.7).
  • An external square/sine wave of 32.768 kHz through 32KXIN with amplitude equal to 1.8 or 1.85 V (see Figure 5-26, Figure 5-27, and Figure 5-28). This configuration is available for the master and slave modes (for more information, see Section 4.7).

5.7.2.3.1 External Crystal Description

Figure 5-24 shows the 32-kHz oscillator block diagram with crystal in master mode.

swcs037-042.gif

NOTE:

Switches close by default and open only if register access enables very-low-power mode when VBAT < 2.7 V.
Figure 5-24 32-kHz Oscillator Block Diagram In Master Mode With Crystal

CXIN and CXOUT represent the total capacitance of the printed circuit board (PCB) and components, excluding the crystal. Their values depend on the datasheet of the crystal, the internal capacitors, and the parallel capacitor. The frequency of the oscillations depends on the value of the capacitors. The crystal must be in the fundamental mode of operation and parallel resonant.

NOTE

For the values of CXIN and CXOUT, see Table 5-48.

Table 5-38 lists the required electrical constraints.

Table 5-38 Crystal Electrical Characteristics

PARAMETER MIN TYP MAX UNIT
Parallel resonance crystal frequency 32.768 kHz
Input voltage, Vin (normal mode) 1.0 1.3 1.55 V
Internal capacitor on each input (Cint) 10 pF
Parallel input capacitance (Cpin) 1 pF
Nominal load cap on each oscillator input CXIN and CXOUT(1) CXIN = CXOUT = Cosc*2 – (Cint + Cpin) pF
Pin-to-pin capacitance 1.6 1.8 pF
Crystal ESR(2) 75
Crystal shunt capacitance, CO 1 pF
Crystal tolerance at room temperature, 25°C –30 30 ppm
Crystal tolerance versus temperature range (–40°C to 85°C) –200 200 ppm
Maximum drive power 1 μW
Operating drive level 0.5 μW
(1) Nominal load capacitor on each oscillator input defined as CXIN = CXOUT = Cosc*2 – (Cint + Cpin). Cosc is the load capacitor defined in the crystal oscillator specification, Cint is the internal capacitor, and Cpin is the parallel input capacitor.
(2) The crystal motional resistance Rm relates to the equivalent series resistance (ESR) by the following formula:
eq1_swcs019.gif
Measured with the load capacitance specified by the crystal manufacturer. If CXIN = CXOUT = 10 pF, CL = 5 pF. Parasitic capacitance from the package and board must also be considered.

When selecting a crystal, the system design must consider the temperature and aging characteristics of a crystal versus the user environment and expected lifetime of the system.

Table 5-39 and Table 5-40 list the switching characteristics of the oscillator and the timing requirements of the 32.768-kHz input clock. Figure 5-25 shows the crystal oscillator output in normal mode.

Table 5-39 Base Oscillator Switching Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
fP Oscillation frequency 32.768 kHz
tSX Start-up time 0.5 s
IDDA Active current consumption LOJIT <1:0> = 00 1.8 μA
LOJIT <1:0> = 11 8
IDDQ Current consumption Low battery mode (1.2 V) 1 μA
Startup 8

Table 5-40 32-kHz Crystal Input Clock Timing Requirements

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
OC0 1/tC(32KHZ) Frequency, 32 kHz 32.768 kHz
OC1 tW(32KHZ) Pulse duration, 32 kHz low or high 0.40*tC(32KHZ) 0.60*tC(32KHZ) μs
SWCS019-019.gifFigure 5-25 32-kHz Crystal Input

5.7.2.3.2 External Clock Description

When an external 32K clock is used instead of a crystal, three configuration can be used:

  • A square- or sine-wave input can be applied to the 32KXIN pin with amplitude of 1.85 or 1.8 V. The 32KXOUT pin can be driven to a dc value of the square- or sine-wave amplitude divided by 2. This configuration, shown in Figure 5-26, is recommended if a large load is applied on the 32KXOUT pin.
  • A square- or sine-wave input can be applied to the 32KXIN pin with amplitude of 1.85 or 1.8 V. The 32KXOUT pin can be left floating. This configuration, showed in Figure 5-27, is used if no charge is applied on the 32KXOUT pin.
  • The oscillator is in bypass mode and a square-wave input can be applied to the 32KXIN pin with amplitude of 1.8 V. The 32KXOUT pin can be left floating. This configuration, shown in Figure 5-28, is used if the oscillator is in bypass mode.
swcs037-041.gif
1. Switches close by default and open only if register access enables very-low-power mode when VBAT < 2.7 V.
Figure 5-26 32-kHz Oscillator Block Diagram Without Crystal Option 1
swcs037-039.gif
1. Switches close by default and open only if register access enables very-low-power mode when VBAT < 2.7 V.
Figure 5-27 32-kHz Oscillator Block Diagram Without Crystal Option 2
swcs037-040.gif
1. Switches close by default and open only if register access enables very-low-power mode when VBAT < 2.7 V.
Figure 5-28 32-kHz Oscillator in Bypass Mode Block Diagram Without Crystal Option 3

Table 5-41 lists the electrical constraints required by the 32-kHz input square- or sine-wave clock.

Table 5-41 32-kHz Input Square- or Sine-Wave Clock Source Electrical Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
f Frequency 32.768 kHz
CI Input capacitance 35 pF
CFI On-chip foot capacitance to GND on each input (see Figure 5-26, Figure 5-27, and Figure 5-28) 10 pF
VPP Square-/sine-wave amplitude in bypass mode or not 1.8(1) V
VIH Voltage input high, square wave in bypass mode 0.8 V
VIL Voltage input low, square wave in bypass mode 0.6 V
(1) Bypass input maximum voltage is the same as the maximum voltage provided for the I/O interface.

Table 5-42 lists the timing requirements of the 32-kHz square-wave input clock.

Table 5-42 32-kHz Square-Wave Input Clock Source Timing Requirements

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
CK0 1/tC(32KHZ) Frequency, 32 kHz 32.768 MHz
CK1 tW(32KHZ) Pulse duration, 32 kHz low or high 0.45*tC(32KHZ) 0.55*tC(32KHZ) μs
CK3 tR(32KHZ) Rise time, 32 kHz(1) 0.1*tC(32KHZ) μs
CK4 tF(32KHZ) Fall time, 32 kHz(1) 0.1*tC(32KHZ) μs
(1) The capacitive load is 30 pF.

Figure 5-29 shows the 32-kHz square- or sine-wave input clock.

swcs037-038.gifFigure 5-29 32-kHz Square- or Sine-Wave Input Clock

5.7.3 Output Clock Specifications

The TPS65920/TPS65930 device provides two output clocks:

  • 32KCLKOUT
  • HFCLKOUT

5.7.3.1 32KCLKOUT Output Clock

Figure 5-30 is the block diagram for the 32.768-kHz clock output.

swcs037-037.gifFigure 5-30 32.768-kHz Clock Output Block Diagram

The TPS65920/TPS65930 device has an internal 32.768-kHz oscillator connected to an external 32.768-kHz crystal through the 32KXIN/32KXOUT balls or an external digital 32.768-kHz clock through the 32KXIN input (see Figure 5-30). The TPS65920/TPS65930 device also generates a 32.768-kHz digital clock through the 32KCLKOUT pin and can broadcast it externally to the application processor or any other devices. The 32KCLKOUT clock is broadcast by default in TPS65920/TPS65930 active mode, but can be disabled if it is not used.

The 32.768-kHz clock (or signal) is also used to clock the RTC embedded in the TPS65920/TPS65930 device. The RTC is not enabled by default. The host processor must set the correct date and time and enable the RTC functionality.

The 32KCLKOUT output buffer can drive several devices (up to 40-pF load). At startup, 32KCLKOUT must be stabilized (frequency/duty cycle) before the signal output. Depending on the startup conditions, this can delay the startup sequence.

Table 5-43 lists the electrical characteristics of the 32KCLKOUT output clock.

Table 5-43 32KCLKOUT Output Clock Electrical Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
f Frequency 32.768 kHz
CL Load capacitance 40 pF
VOUT Output clock voltage, depending on output reference level IO_1P8 (see Section 3) 1.8(1) V
VOH Voltage output high VOUT – 0.45 VOUT V
VOL Voltage output low 0 0.45 V
(1) The output voltage depends on the output reference level, which is IO_1P8 (see Section 3).

Table 5-44 lists the output clock switching characteristics. Figure 5-31 shows the 32KCLKOUT output clock waveform.

Table 5-44 32KCLKOUT Output Clock Switching Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
CK0 1/tC(32KCLKOUT) Frequency 32.768 MHz
CK1 tW(32KCLKOUT) Pulse duration, 32KCLKOUT low or high 0.40*tC(32KCLKOUT) 0.60*tC(32KCLKOUT) ns
CK2 tR(32KCLKOUT) Rise time, 32KCLKOUT(1) 16 ns
CK3 tF(32KCLKOUT) Fall time, 32KCLKOUT(1) 16 ns
(1) The output capacitive load is 30 pF.
swcs037-035.gifFigure 5-31 32KCLKOUT Output Clock

5.7.3.2 HFCLKOUT Output Clock

Table 5-45 lists the electrical characteristics of the HFCLKOUT output clock.

Table 5-45 HFCLKOUT Output Clock Electrical Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
f Frequency 19.2, 26, or 38.4 MHz
CL Load capacitance 30 pF
VOUT Output clock voltage, depending on output reference level IO_1P8 (see Section 3) 1.8(1) V
VOH Voltage output high VOUT – 0.45 VOUT V
VOL Voltage output low 0 0.45 V
(1) The output voltage depends on the output reference level, which is IO_1P8 (see Section 3).

Table 5-46 lists the switching characteristics of the HFCLKOUT output clock.

Table 5-46 HFCLKOUT Output Clock Switching Characteristics

NAME PARAMETER DESCRIPTION MIN TYP MAX UNIT
CHO1 1/tC(HFCLKOUT) Frequency 19.2, 26, or 38.4 MHz
CHO2 tW(HFCLKOUT) Pulse duration, HFCLKOUT low or high 0.40*tC(HFCLKOUT) 0.60*tC(HFCLKOUT) ns
CHO3 tR(HFCLKOUT) Rise time, HFCLKOUT(1) 2.6 ns
CHO4 tF(HFCLKOUT) Fall time, HFCLKOUT(1) 2.6 ns
(1) The output capacitive load is 30 pF.

Figure 5-32 shows the HFCLKOUT output clock waveform.

swcs037-036.gifFigure 5-32 HFCLKOUT Output Clock

5.7.3.3 Output Clock Stabilization Time

Figure 5-33 shows the 32KCLKOUT and HFCLKOUT clock stabilization time.

swcs037-034.gif

NOTE:

Tstartup, Delay1, and Delay2 depend on the boot mode (see Section 5.1.5).

NOTE:

Ensure that the high frequency oscillator start-up time is in spec for the boot mode used. During power-up the internal delay, Delay1 above is fixed (5.2 ms and 5.3 ms depending on boot mode). The start-up time for the oscillator must be less than the fixed delay.
Figure 5-33 32KCLKOUT and HFCLKOUT Clock Stabilization Time

Figure 5-34 shows the HFCLKOUT behavior.

SWCS019-028.gifFigure 5-34 HFCLKOUT Behavior

5.8 Debouncing Time

Table 5-47 lists the characteristics of debouncing.

Table 5-47 Debouncing

DEBOUNCING FUNCTIONS BLOCK PROGRAMMABLE DEBOUNCING TIME DEFAULT
USB plug detection USB No 9x50 ms 9x50 ms
Plug/unplug detection VBUS(1) USB Yes 0 to 250 ms
(32/32468-second steps)
28 ms
Plug/unplug detection ID(2) USB Yes 0 to 250 ms
(32/32468-second steps)
50 ms
Debouncing function interrupt generation debounce for VBUS and ID(3) Power Yes 0 to 250 ms 30 ms
Hot-die detection Thermistor No 60 μs 60 μs
Thermal shutdown detection No 60 μs 60 μs
PWRON(4) Start/stop button No 31.25 ms 31.25 ms
NRESWARM Button reset No 60 μs 60 μs
SIM card plug/unplug GPIO Yes 0 or 30 ms ± 1 ms 0 ms
MMC1 (plug/unplug) GPIO Yes 0 or 30 ms ± 1 ms 0 ms
(1) Programmable in the VBUS_DEBOUNCE register
(2) Programmable in the ID_DEBOUNCE register
(3) Programmable in the RESERVED_E[2:0] CFG_VBUSDEB register
(4) The PWRON signal is debounced 1024*CLK32K (maximum 1026*CLK32K) falling edge in master mode.

Figure 5-35 is a sample debouncing sequence chronogram.

swcs037-029.gifFigure 5-35 Debouncing Sequence Chronogram Example

Event1 is correctly debounced after 5 ms. Event2 is debounced after 50ms + dT because the capture of the event is considered after the next rising edge of the 50-ms clock.

5.9 External Components

Table 5-48 lists the TPS65920/TPS65930 device external components.

Table 5-48 TPS65920/TPS65930 External Components

FUNCTION COMPONENT REFERENCE VALUE NOTE LINK
Power Supplies
VDD1 Capacitor CVDD1.IN 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Figure 5-1
Capacitor CVDD1.OUT 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Inductor LVDD1 1 μH Range ± 30%
DCR max = 100 mΩ
VDD2 Capacitor CVDD2.IN 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Figure 5-1
Capacitor CVDD2.OUT 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Inductor LVDD2 1 μH Range ± 30%
DCR max = 100 mΩ
VIO Capacitor CVIO.IN 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Figure 5-1
Capacitor CVIO.OUT 10 μF Range ± 50%
ESR min = 1 mΩ
ESR max = 20 mΩ
Taiyo Yuden: JMK212BJ106KD
Inductor LVVIO 1 μH Range ± 30%
DCR max = 100 mΩ
VRUSB_3V Capacitor CVUSB.3P1 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 300 mΩ
Figure 5-1Figure 5-13
VRUSB_1V5 Capacitor CVINTUSB1P5.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1Figure 5-13
VRUSB_1V8 Capacitor CVINTUSB1P8.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1Figure 5-13
VDAC Capacitor CVDAC.IN 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
Capacitor CVDAC.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
VPLLA3R Capacitor CVPLLA3R.IN 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VPLL1 Capacitor CVPLL1.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VMMC1 Capacitor CVMMC1.IN 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
Capacitor CVMMC1.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
VAUX12S Capacitor CVAUX12S.IN 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VAUX2 Capacitor CVAUX2.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VINT Capacitor CVINT.IN 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VINTANA1 Capacitor CVINTANA1.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VINTANA2 Capacitor CVINTANA2.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VINTDIG Capacitor CVINTDIG.OUT 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-1
VBAT.USB Capacitor CVBAT.USB 1 μF Range: 0.3 to 2.7 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Figure 5-13
USB CP Capacitor CVBUS.FC 2.2 μF ± 40% ESR max = 20 mΩ Figure 5-13
Capacitor CVBUS.IN 10 μF
Capacitor CVBUS 4.7 μF ± 40% ESR max = 20 mΩ
32.768 kHz
32K OSC Capacitor CXIN 10 pF Range: 9 pF to 12.5 pF Figure 5-24
Capacitor CXOUT 10 pF
Quartz X32.768kHz 32.768 kHz ±30 ppm (at 25°C)
±200 ppm (–40°C to 85°C)
Audio
External class-D predriver left Capacitor CPL.O 50 pF Figure 6-2
Capacitor CPL 1 μF
Resistor RPL >15 kΩ
Resistor RPL.M >15 kΩ
Resistor RPL.O 10 kΩ
Capacitor CPL.M 1 μF
External class-D predriver right Capacitor CPR.O 50 pF Figure 6-2
Capacitor CPR 1 μF
Resistor RPR >15 kΩ
Resistor RPR.M >15 kΩ
Resistor RPR.O 10 kΩ
Capacitor CPR.M 1 μF
Vibrator H-bridge Ferrite bead LV.M BLM18BD221S1N Figure 6-3
Ferrite bead LV.P BLM18BD221S1N
Capacitor CV.V 1 μF
Capacitor CV.M 1 nF
Capacitor CV.P 1 nF
MIC main (pseudo differential mode) Capacitor CMM.M 100 nF Figure 6-6
Capacitor CMM.P 100 nF
Capacitor CMM.O 47 pF
Resistor RMM.O ~500 Ω
Resistor RMM.MP ~1.7 kΩ
Capacitor CMM.B 0 to 200 pF If greater than 200 pF, a serial resistor is required for bias stability
MIC main (differential mode) Capacitor CMM.M 100 nF Figure 6-7
Capacitor CMM.P 100 nF
Capacitor CMM.PM 47 pF
Capacitor CMM.O 47 pF
Capacitor CMM.GM 47 pF
Capacitor CMM.GP 47 pF
Resistor RMM.BP 1 kΩ
Resistor RMM.GM 1 kΩ
Capacitor CMM.B 0 to 200 pF If greater than 200 pF, a serial resistor is required for bias stability
VMIC1 Capacitor CVMIC1.OUT 1 μF Range: 0.3 μF to 3.3 μF
ESR min = 20 mΩ
ESR max = 600 mΩ
Silicon MIC Capacitor CSM 1 μF Figure 6-8
Capacitor CSM.P 100 nF
Capacitor CSM.M 100 nF
Capacitor CSM.PG 47 nF
Resistor RSM >500 Ω
Auxiliary right Capacitor CAUXR 100 nF Figure 6-9
Capacitor CAUXR.M 47 pF
LED Driver
LED Resistor RLED.A 120 Ω Needed for each LED Figure 5-18
Resistor RLED.B 160 kΩ Needed for each LED
I2C Bus—External Pullup
I2C SmartReflex Resistor RPSR.SDA Pullups for various bus capacitances (CL) and I2C speeds (Std, Fast, and HS)
If CL = 10 pF: Std = 118 kΩ, Fast = 35.4 kΩ, HS = 4.7 kΩ
If CL = 12 pF: Std = 98.3 kΩ, Fast = 29.5 kΩ, HS = 3.9 kΩ
If CL = 50 pF: Std = 23.6 kΩ, Fast = 7.1 kΩ, HS = 940 Ω
If CL = 100 pF: Std = 11.8 kΩ, Fast = 3.54 kΩ, HS = 470 Ω
If CL ≤ 12 pF, there is no need for an external pullup, the internal 3-kΩ pullup can be used.
If an external pullup is used, disable the internal 3-kΩ pullup (reference the GPPUPDCTR1 register; see the TRM).
Section 4.7.3
Resistor RPSR.SCL
I2C control Resistor RCNTL.SD;
Resistor RCNTL.SCL