SNVSAC7C October 2015 – May 2017
PRODUCTION DATA.
The TPS61193-Q1 is a highly integrated LED driver for automotive infotainment, lighting systems, and medium-sized LCD backlight applications. It includes a DC-DC with an integrated FET, supporting both boost and SEPIC modes, an internal LDO enabling direct connection to battery without need for a pre-regulated supply and three LED current sinks. The VDDIO/EN pin provides the supply voltage for digital IOs (PWM and SYNC inputs) and at the same time enables the device.
The switching frequency on the DC-DC converter is set by a resistor connected to the FSET pin. The maximum voltage of the DC-DC is set by a resistive divider connected to the FB pin. For the best efficiency the output voltage is adapted automatically to the minimum necessary level needed to drive the LED strings. This is done by monitoring LED output voltage drop in real time. For EMI reduction and control two optional features are available:
The three constant current sinks OUT1, OUT2, and OUT3 provide LED current up to 100 mA. Value for the current per OUT pin is set with a resistor connected to ISET pin. Current sinks that are not used must be connected to ground. Grounded current sink is disabled and excluded from adaptive voltage detection loop.
Brightness is controlled with the PWM input. Frequency range for the input PWM is from 100 Hz to 20 kHz. LED output PWM follows the input PWM so the output frequency is equal to the input frequency.
TPS61193-Q1 has extensive fault detection features :
Fault condition is indicated through the FAULT output pin.
The TPS61193-Q1 DC-DC converter generates supply voltage for the LEDs and can operate in boost mode or in SEPIC mode. The maximum output voltage VOUT_MAX is defined by an external resistive divider (R1, R2).
VOUT_MAX voltage should be chosen based on the maximum voltage required for LED strings. Recommended maximum voltage is about 30% higher than maximum LED string voltage. DC-DC output voltage is adjusted automatically based on LED current sink headroom voltage. Maximum, minimum, and initial boost voltages can be calculated with :
where
Alternatively, a T-divider can be used if resistance less than 100 kΩ is required for the external resistive divider. Refer to Using the TPS61193-Q1 Evaluation Module for details.
The converter is a current mode DC-DC converter, where the inductor current is measured and controlled with the feedback. Switching frequency is adjustable between 250 kHz and 2.2 MHz with RFSET resistor as Equation 2:
where
In most cases lower frequency has higher system efficiency. DC-DC internal parameters are chosen automatically according to the selected switching frequency (see Table 2) to ensure stability. In boost mode a 15-pF capacitor CFB must be placed across resistor R1 when operating in 300-kHz to 500-kHz range (see Typical Application for 3 LED Strings). When operating in the 1.8-MHz to 2.2-MHz range CFB = 4.7 pF.
DC-DC can be driven by an external SYNC signal between 300 kHz and 2.2 MHz. If the external synchronization input disappears, DC-DC continues operation at the frequency defined by RFSET resistor. When external frequency disappears and SYNC pin level is low, converter continues operation without spread spectrum immediately. If SYNC remains high, converter continues switching with spread spectrum enabled after 256 µs.
External SYNC frequency must be 1.2 to 1.5 times higher than the frequency defined by RFSET resistor. Minimum frequency setting with RFSET is 250 kHz to support 300-kHz switching with external clock.
The optional spread spectrum feature (±3% from central frequency, 1-kHz modulation frequency) reduces EMI noise at the switching frequency and its harmonic frequencies. When external synchronization is used, spread spectrum is not available.
SYNC PIN INPUT | MODE |
---|---|
Low | Spread spectrum disabled |
High | Spread spectrum enabled |
300 to 2200 kHz frequency | Spread spectrum disabled, external synchronization mode |
RANGE | FREQUENCY (kHz) | TYPICAL INDUCTANCE (µH) |
TYPICAL BOOST INPUT AND OUTPUT CAPACITORS (µF) |
MINIMUM SWITCH OFF TIME (ns)(2) |
BLANK TIME (ns) |
CURRENT RAMP (A/s) |
CURRENT RAMP DELAY (ns) |
---|---|---|---|---|---|---|---|
1 | 300 to 480 | 33 | 2 ×10 (cer.) + 33 (electr.) | 150 | 95 | 24 | 550 |
2 | 480 to 1150 | 15 | 10 (cer.) + 33 (electr.) | 60 | 95 | 43 | 300 |
3 | 1150 to 1650 | 10 | 3 × 10 (cer.) | 40 | 95 | 79 | 0 |
4 | 1650 to 2200 | 4.7 | 3 × 10 (cer.) | 40 | 70 | 145 | 0 |
The converter SW pin DC current is limited to 2 A (typical). To support warm-start transient conditions the current limit is automatically increased to 2.5 A for a short period of 1.5 seconds when a 2-A limit is reached.
NOTE
Application condition where the 2-A limit is exceeded continuously is not allowed. In this case the current limit would be 2 A for 1.5 seconds followed by 2.5-A limit for 1.5 seconds, and this 3-second period repeats.
To keep switching voltage within safe levels there is a 48-V limit comparator in the event that FB loop is broken.
The internal LDO regulator converts the input voltage at VIN to a 4.3-V output voltage for internal use. Connect a minimum of 1-µF ceramic capacitor from LDO pin to ground, as close to the LDO pin as possible.
TPS61193-Q1 detects LED output configuration during start-up. Any current sink output connected to ground is disabled and excluded from the adaptive voltage control of the DC-DC and fault detections.
Maximum current for the LED outputs is controlled with external RISET resistor. RISET value for target maximum current can be calculated using Equation 3:
where
The TPS61193-Q1 has fault detection for LED open and short, VIN input overvoltage protection (VIN_OVP) , VIN undervoltage lockout (VIN_UVLO), and thermal shutdown (TSD).
Adaptive voltage control function adjusts the DC-DC output voltage to the minimum sufficient voltage for proper LED current sink operation. The current sink with highest VF LED string is detected and DC-DC output voltage adjusted accordingly. DC-DC adaptive control voltage step size is defined by maximum voltage setting, VSTEP = (VOUT_MAX – VOUT_MIN) / 256. Periodic down pressure is applied to the target voltage to achieve better system efficiency.
Every LED current sink has 3 comparators for the adaptive DC-DC control and LED fault detections. Comparator outputs are filtered, filtering time is 1 µs.
Figure 12 shows different cases which cause DC-DC voltage increase, decrease, or generate faults. In normal operation voltage at all the OUT# pins is between LOW_COMP and MID_COMP levels, and boost voltage stays constant. LOW_COMP level is the minimum for proper LED current sink operation, 1.1 × VSAT + 0.2 V (typical). MID_COMP level is 1.1 × VSAT + 1.2 V (typical) so typical headroom window is 1 V.
When voltage at all the OUT# pins increases above MID_COMP level, DC-DC voltage adapts downwards.
When voltage at any of the OUT# pins falls below LOW_COMP threshold, DC-DC voltage adapts upwards. In the condition where DC-DC voltage reaches the maximum and there are one or more outputs still below LOW_COMP level, an open LED fault is detected.
HIGH_COMP level, 6 V typical, is the threshold for shorted LED detection. When the voltage of one or more of the OUT# pins increases above HIGH_COMP level and at least one of the other outputs is within the normal headroom window, shorted LED fault is detected.
A summary of the TPS61193-Q1 fault detection behavior is shown in Table 3. Detected faults (excluding LED open or short) cause device to enter FAULT_RECOVERY state. In FAULT_RECOVERY the DC-DC and LED current sinks of the device are disabled, and the FAULT pin is pulled low. The device recovers automatically and enters normal operating mode (ACTIVE) after a recovery time of 100 ms if the fault condition has disappeared. When recovery is succesful, FAULT pin is released.
If a LED fault is detected, the device continues normal operation and only the faulty string is disabled. The fault is indicated via the FAULT pin which can be released by toggling VDDIO/EN pin low for a short period of 2 µs to 20 µs. LEDs are turned off for this period but the device stays in ACTIVE mode. If VDDIO/EN is low longer, the device goes to STANDBY and restarts when EN goes high again.
FAULT/ PROTECTION |
FAULT NAME | THRESHOLD | FAULT PIN | FAULT_ RECOVERY STATE |
ACTION |
---|---|---|---|---|---|
VIN overvoltage protection | VIN_OVP | 1. VIN > 42 V 2. VOUT > VSET_DCDC + 6..10 V. VSET_DCDC is voltage value defined by logic during adaptation |
Yes | Yes | 1. Overvoltage is monitored from the beginning of soft start. Fault is detected if the duration of overvoltage condition is 100 µs minimum. 2. Overvoltage is monitored from the beginning of normal operation (ACTIVE mode). Fault is detected if over-voltage condition duration is 560 ms minimum (tfilter). After the first fault, detection filter time is reduced to 50 ms for following recovery cycles. When the device recovers and has been in ACTIVE mode for 160 ms, filter time is increased back to 560 ms . |
VIN undervoltage lockout | VIN_UVLO | Falling 3.9 V Rising 4 V |
Yes | Yes | Detects undervoltage condition at VIN pin. Sensed in all operating modes. Fault is detected if undervoltage condition duration is 100 µs minimum. |
Open LED fault | OPEN_LED | LOW_COMP threshold | Yes | No | Detected if the voltage of one or more current sinks is below threshold level, and DC-DC adaptive control has reached maximum voltage. Open string is removed from the DC-DC voltage control loop and current sink is disabled. Fault pin is released by toggling VDDIO/EN pin. If VDDIO/EN is low for a period of 2 µs to 20 µs, LEDs are turned off for this period but device stays ACTIVE. If VDDIO/EN is low longer, device goes to STANDBY and restarts when EN goes high again. |
Shorted LED fault | SHORT_LED | Shorted string detection level 6 V | Yes | No | Detected if the voltage of one or more current sinks is above shorted string detection level and at least one OUTx voltage is within headroom window. Shorted string is removed from the DC-DC voltage control loop and current sink is disabled. Fault pin is released by toggling VDDIO/EN pin. If VDDIO/EN is low for a period of 2…20 µs, LEDs are turned off for this period but device stays ACTIVE. If VDDIO/EN is low longer, device goes to STANDBY and restarts when EN goes high again.. |
Thermal protection | TSD | 165ºC Thermal shutdown hysteresis 20ºC |
Yes | Yes | Thermal shutdown is monitored from the beginning of soft start. Die temperature must decrease by 20ºC for device to recover. |
The TPS61193-Q1 enters STANDBY mode when the internal LDO output rises above the power-on reset level, VLDO > VPOR. In STANDBY mode the device is able to detect VDDIO/EN signal. When VDDIO/EN is pulled high, the device powers up. After start LED outputs are sensed to detect grounded outputs. Grounded outputs are disabled and excluded from the adaptive voltage control loop of the DC-DC.
If a fault condition is detected, the device enters FAULT_RECOVERY state. Faults that cause the device to enter FAULT_RECOVERY are listed in Table 3. When LED open or short is detected, the faulty string is disabled, but device stays in ACTIVE mode.