8.3.1 VRTC Output and Operation With or Without Backup Battery

The VRTC pin is an always-on output, intended to supply up to 30 mA to a permanently required rail (that is, for a real-time clock). The TPS650231 asserts the RESPWRON signal if VRTC drops below 2.4 V. VRTC is selected from a priority scheme based on the VSYSIN and VBACKUP inputs.

When the voltage at the VSYSIN pin exceeds 2.65 V, VRTC connects to the VSYSIN input through a PMOS switch and all other paths to VRTC are disabled. The PMOS switch drops a maximum of 375 mV at 30-mA, which must be considered when using VRTC. VSYSIN can be connected to any voltage source with the appropriate input voltage, including VCC or, if set to 3.3-V output, DCDC2 or DCDC3. When VSYSIN falls below 2.65 V or shorts to ground, the PMOS switch connecting VRTC and VSYSIN opens and VRTC then connects to either VBACKUP or the output of a dedicated 3-V or 30-mA LDO. Texas Instruments recommends connecting VSYSIN to VCC or ground, connecting VCC if a non-replaceable primary cell is connected to VBACKUP and ground if the VRTC output floats.

If the PMOS switch between VSYSIN and VRTC is open and VBACKUP exceeds 2.65 V, VRTC connects to VBACKUP through a PMOS switch. The PMOS switch drops a maximum of 375 mV at 30 mA, which must be considered if using VRTC. A typical application may connect VBACKUP to a primary Li button cell, but any battery that provides a voltage between 2.65 V and 6 V (that is, a single Li-Ion cell or a single boosted NiMH battery) is acceptable, to supply the VRTC output.

If the switches between VRTC and VSYSIN or VBACKUP are open, the dedicated 3-V or 30-mA LDO, driven from V_CC, connects to VRTC. This LDO is disabled if the voltage at the VSYSIN input exceeds 2.65 V.

Inside TPS650231 there is a switch (Vmax switch) which selects the higher voltage between V_CC and VBACKUP. This is used as the supply voltage for some basic functions. The functions powered from the output of the Vmax switch are:

• INT output
• RESPWRON output
• HOT_RESET input
• LOW_BATT output
• PWRFAIL output
• Enable pins for DC-DC converters, LDO1 and LDO2
• Undervoltage lockout comparator (UVLO)
• Reference system with low-frequency timing oscillators
• LOW_BATT and PWRFAIL comparators

The main 2.25-MHz oscillator, and the I²C interface are only powered from V_CC.

spacer

A. V_VSYSIN, V_VBACKUP thresholds: falling = 2.55 V, rising = 2.65 V ±3%

B. RESPWRON thresholds: falling = 2.4 V, rising = 2.52 V ±3%

Figure 32. RTC and RESPWRON

8.3.2 Step-Down Converters, VDCDC1, VDCDC2, and VDCDC3

The TPS650231 incorporates three synchronous step-down converters operating typically at 2.25-MHz fixed-frequency pulse width modulation (PWM) at moderate to heavy-load currents. At light-load currents the converters automatically enter power save mode and operate with pulse frequency modulation (PFM). The VDCDC1 converter is capable of delivering 1.7-A output current, the VDCDC2 converter is capable of delivering 1.2-A, and the VDCDC3 converter delivers up to 800 mA.

The converter output voltages can be programmed through the DEFDCDC1, DEFDCDC2, and DEFDCDC3 pins. For DEFDCDC1 and DEFDCDC3, the pins can either be connected to GND, VCC, or to a resistor divider between the output voltage and GND.

The VDCDC1 converter defaults to 1.2 V or 1.6 V depending on the DEFDCDC1 configuration pin, if DEFDCDC1 is tied to ground the default is 1.2 V, if it is tied to VCC the default is 1.6 V. When the DEFDCDC1 pin is connected to a resistor divider, the output voltage can be set in the range of 0.6 V to VINDCDC1 V. See Application Information for more details. The core voltage can be reprogrammed through the serial interface in the range of 0.8 V to 1.6 V with a programmable slew rate. The converter is forced into PWM operation whilst any programmed voltage change is underway, whether the voltage is being increased or decreased. The DEFCORE and DEFSLEW registers are used to program the output voltage and slew rate during voltage transitions.

The DEFDCDC2 pin does not have the logic function in parallel and always needs to be connected with a resistor divider, the output voltage can be set in the range of 0.6 V to VINDCDC2 V.

The VDCDC3 converter defaults to 1.8 V or 3.3 V depending on the DEFDCDC3 configuration pin. If DEFDCDC3 is tied to ground, the default is 1.8 V. If it is tied to VCC, the default is 3.3 V. When the DEFDCDC3 pin is connected to a resistor divider, the output voltage can be set in the range of 0.6 V to VINDCDC3 V. The step-down converter outputs (when enabled) are monitored by power-good comparators, the outputs of which are available through the serial interface. The outputs of the DC-DC converters can be optionally discharged through on-chip 300-Ω resistors when the DC-DC converters are disabled.

During PWM operation the converters use a unique fast response voltage mode controller scheme with input voltage feedforward to achieve good line and load regulation allowing the use of small ceramic input and output capacitors. At the beginning of each clock cycle initiated by the clock signal, the P-channel MOSFET switch is turned on and the inductor current ramps up until the comparator trips and the control logic turns off the switch. The current limit comparator also turns off the switch in case the current limit of the P-channel switch is exceeded. After the adaptive dead-time used to prevent shoot through current, the N-channel MOSFET rectifier is turned on and the inductor current ramps down. The next cycle is initiated by the clock signal again turning off the N-channel rectifier and turning on the P-channel switch.

The three DC-DC converters operate synchronized to each other, with the VDCDC1 converter as the master. A 180° phase shift between the VDCDC1 switch turn on and the VDCDC2 and a further 90° shift to the VDCDC3 switch turn on decreases the input RMS current and smaller input capacitors can be used. The phase of the three converters can be changed using the CON_CTRL register.

8.3.3 Power Save Mode Operation

As the load current decreases, the converters enter the power save mode operation. During power save mode, the converters operate in a burst mode (PFM mode) with a frequency between 750 kHz and 2.25 MHz, nominal for one burst cycle. However, the frequency between different burst cycles depends on the actual load current and is typically far less than the switching frequency with a minimum quiescent current to maintain high efficiency.

To optimize the converter efficiency at light load, the average current is monitored and if in PWM mode the inductor current remains below a certain threshold, then PSM is entered. The typical threshold to enter PSM is calculated with Equation 1, Equation 2, and Equation 3.

Equation 1.

Equation 2.

Equation 3.

During the power save mode the output voltage is monitored with a comparator, and by maximum skip burst width. As the output voltage falls below the threshold, set to the nominal V_O, the P-channel switch turns on and the converter effectively delivers a constant current defined with Equation 4, Equation 5, and Equation 6.

Equation 4.

Equation 5.

Equation 6.

If the load is below the delivered current then the output voltage rises until the same threshold is crossed in the other direction. All switching activity ceases, reducing the quiescent current to a minimum until the output voltage has again dropped below the threshold. The power save mode is exited, and the converter returns to PWM mode if either of the following conditions are met:

1. the output voltage drops 2% below the nominal V_O due to increasing load current
2. the PFM burst time exceeds 16 × 1 / fs (7.11 μs typical).

These control methods reduce the quiescent current to typically 14 μA per converter, and the switching activity to a minimum, thus achieving the highest converter efficiency. Setting the comparator thresholds at the nominal output voltage at light-load current results in a low-output voltage ripple. The ripple depends on the comparator delay and the size of the output capacitor. Increasing capacitor values makes the output ripple tend to zero. The PSM is disabled through the I²C interface to force the individual converters to stay in fixed-frequency PWM mode.

8.3.4 Low-Ripple Mode

Setting bit 3 in register CON-CTRL to 1 enables the low-ripple mode for all of the DC-DC converters if operated in PFM mode. For an output current less than approximately 10 mA, the output voltage ripple in PFM mode is reduced, depending on the actual load current. The lower the actual output current on the converter, the lower the output ripple voltage. For an output current above 10 mA, there is only minor difference in output voltage ripple between PFM mode and low-ripple PFM mode. As this feature also increases switching frequency, it is used to keep the switching frequency above the audible range in PFM mode down to a low-output current.

8.3.5 Soft-Start

Each of the three converters has an internal soft-start circuit that limits the inrush current during start-up. The soft-start is realized by using a low current to initially charge the internal compensation capacitor. The soft-start time is typically 750 μs if the output voltage ramps from 5% to 95% of the final target value. If the output is already precharged to some voltage when the converter is enabled, then this time is reduced proportionally. There is a short delay of typically 170 μs between the converter being enabled and switching activity actually starting. This allows the converter to bias itself properly, to recognize if the output is precharged, and if so to prevent discharging of the output while the internal soft-start ramp catches up with the output voltage.

8.3.6 100% Duty Cycle Low-Dropout Operation

The TPS650231 converters offer a low input-to-output voltage difference while still maintaining operation with the use of the 100% duty cycle mode. In this mode the P-channel switch is constantly turned on. This is particularly useful in battery-powered applications to achieve longest operation time by taking full advantage of the whole battery voltage range. The minimum input voltage required to maintain DC regulation depends on the load current and output voltage. It is calculated in Equation 7.

Equation 7.

where

• Iout_max = maximum load current (Note: ripple current in the inductor is zero under these conditions)
• r_DS(on)max = maximum P-channel switch r_DS(on)
• R_L = DC resistance of the inductor
• Vout_min = nominal output voltage minus 2% tolerance limit

8.3.7 Active Discharge When Disabled

When the VDCDC1, VDCDC2, and VDCDC3 converters are disabled, due to an UVLO, DCDC_EN, or OVERTEMP condition, it is possible to actively pull down the outputs. This feature is disabled per default and is individually enabled through the CON_CTRL2 register in the serial interface. When this feature is enabled, the VDCDC1, VDCDC2, and VDCDC3 outputs are discharged by a 300-Ω (typical) load which is active as long as the converters are disabled.

8.3.8 Power-Good Monitoring

All three step-down converters and both the LDO1 and LDO2 linear regulators have power-good comparators. Each comparator indicates when the relevant output voltage has dropped 10% below its target value with 5% hysteresis. The outputs of these comparators are available in the PGOODZ register through the serial interface. An interrupt is generated when any voltage rail drops below the 10% threshold. The comparators are disabled when the converters are disabled and the relevant PGOODZ register bits indicate that power is good.

8.3.9 Low-Dropout Voltage Regulators

The low-dropout voltage regulators are designed to operate well with low-value ceramic input and output capacitors. They operate with input voltages down to 1.5 V. The LDOs offer a maximum dropout voltage of 300 mV at rated output current. Each LDO supports a current limit feature. Both LDOs are enabled by the LDO_EN pin, both LDOs can be disabled or programmed through the serial interface using the REG_CTRL and LDO_CTRL registers. The LDOs also have reverse conduction prevention. This allows the possibility to connect external regulators in parallel in systems with a backup battery. The TPS650231 step-down and LDO voltage regulators automatically power down when the V_CC voltage drops below the UVLO threshold or when the junction temperature rises above 160°C.

8.3.10 Undervoltage Lockout

The undervoltage lockout circuit for the five regulators on the TPS650231 prevents the device from malfunctioning at low-input voltages and from excessive discharge of the battery. It disables the converters and LDOs. The UVLO circuit monitors the VCC pin, the threshold is set internally to 2.35 V with 5% (120 mV) hysteresis. Consider this current if an external RC filter is used at the VCC pin to remove switching noise from the TPS650231 internal analog circuitry supply.

8.3.11 Power-Up Sequencing

The TPS650231 power-up sequencing is designed to be entirely flexible and customer-driven. This is achieved by providing separate enable pins for each switch-mode converter, and a common enable signal for the LDOs. The relevant control pins are described in Table 2.

8.3.12 System Reset + Control Signals

The RESPWRON signal can be used as a global reset for the application. It is an open-drain output. The RESPWRON signal is generated according to the power good comparator of VRTC, and remains low for t_nrespwron seconds after VRTC has risen above 2.52 V (falling threshold is 2.4 V, 5% hysteresis). t_nrespwron is set by an external capacitor at the TRESPWRON pin. 1 nF gives typically 100 ms. RESPWRON is also triggered by the HOT_RESET input. This input is internally debounced, with a filter time of typically 30 ms.

The PWRFAIL and LOW_BAT signals are generated by two voltage detectors using the PWRFAIL_SNS and LOWBAT_SNS input signals. Each input signal is compared to a 1-V threshold (falling edge) with 5% (50 mV) hysteresis.

The DCDC1 converter is reset to its default output voltage defined by the DEFDCDC1 input, when HOT_RESET is asserted. Other I²C registers are not affected. Generally, the DCDC1 converter is set to its default voltage with one of these conditions: HOT_RESET active, VRTC lower than its threshold voltage, undervoltage lockout (UVLO) condition, or RESPWRON active.

The RESPWRON, HOT_RESET, LOW_BAT, and LOWBAT_SNS pins are not available in TPS650231YFF.

8.5.1 Serial Interface

The serial interface is compatible with the standard and fast mode I²C specifications, allowing transfers at up to 400 kHz. The interface adds flexibility to the power supply solution, enabling most functions to be programmed to new values depending on the instantaneous application requirements and charger status to be monitored. Register contents remain intact as long as V_CC remains above 2 V. The TPS650231 has a 7-bit address: 1001000, other addresses are available upon contact with the factory. Attempting to read data from the register addresses not listed in this section results in FFh being read out.

For normal data transfer, DATA is allowed to change only when CLK is low. Changes when CLK is high are reserved for indicating the start and stop conditions. During data transfer, the data line must remain stable whenever the clock line is high. There is one clock pulse per bit of data. Each data transfer is initiated with a start condition and terminated with a stop condition. When addressed, the TPS650231 device generates an acknowledge bit after the reception of each byte. The master device (microprocessor) must generate an extra clock pulse that is associated with the acknowledge bit. The TPS650231 device must pull down the DATA line during the acknowledge clock pulse so that the DATA line is a stable low during the high period of the acknowledge clock pulse. The DATA line is a stable low during the high period of the acknowledge–related clock pulse. Setup and hold times must be taken into account. During read operations, a master must signal the end of data to the slave by not generating an acknowledge bit on the last byte that was clocked out of the slave. In this case, the slave TPS650231 device must leave the data line high to enable the master to generate the stop condition

Figure 33. Bit Transfer on the Serial Interface

Figure 34. START and STOP Conditions

Figure 35. Serial I/F WRITE to TPS650231 Device

Figure 36. Serial I/F READ from TPS650231: Protocol A

Figure 37. Serial I/F READ from TPS650231: Protocol B

8.6.1 VERSION Register Address: 00h (Read Only)

8.6.2 PGOODZ Register Address: 01h (Read Only)

8.6.3 MASK Register Address: 02h (Read or Write), Default Value: C0h

The MASK register can be used to mask particular fault conditions from appearing at the INT pin. MASK<n> = 1 masks PGOODZ<n>.

8.6.4 REG_CTRL Register Address: 03h (Read or Write), Default Value: FFh

The REG_CTRL register is used to disable or enable the power supplies through the serial interface. The contents of the register are logically AND’ed with the enable pins to determine the state of the supplies. A UVLO condition resets the REG_CTRL to 0xFF, so the state of the supplies defaults to the state of the enable pin. The REG_CTRL bits are automatically reset to default when the corresponding enable pin is low.

8.6.5 CON_CTRL Register Address: 04h (Read or Write), Default Value: B1h

The CON_CTRL register is used to force any or all of the converters into forced PWM operation, when low-output voltage ripple is vital. It is also used to control the phase shift between the three converters to minimize the input rms current, hence reduce the required input blocking capacitance. The DCDC1 converter is taken as the reference and consequently has a fixed zero phase shift.

8.6.6 CON_CTRL2 Register Address: 05h (Read or Write), Default Value: 40h

The CON_CTRL2 register can be used to take control the inductive converters.

RESET(1): CON_CTRL2[6] is reset to its default value by one of these events:

• Undervoltage lockout (UVLO)
• HOT_RESET pulled low
• RESPWRON active
• VRTC below threshold

8.6.7 DEFCORE Register Address: 06h (Read or Write), Default Value: 14h/1Eh

RESET(1): DEFCORE is reset to its default value by one of these events:

• Undervoltage lockout (UVLO)
• HOT_RESET pulled low
• RESPWRON active
• VRTC below threshold

8.6.8 DEFSLEW Register Address: 07h (Read or Write), Default Value: 06h

8.6.9 LDO_CTRL Register Address: 08h (Read or Write), Default Value: Set with DEFLDO1 and DEFLDO2

The LDO_CTRL registers can be used to set the output voltage of LDO1 and LDO2. LDO_CTRL[7] and LDO_CTRL[3] are reserved and must always be written to 0.

The default voltage is set with DEFLDO1 and DEFLDO2 pins as described in Table 3.