SNVU821 November   2023 TPS92642-Q1

 

  1.   1
  2.   TPS92642EVM-203 5-A Synchronous Buck IR LED Driver Evaluation Module
  3.   Trademarks
  4. 1Introduction
  5. 2Warnings and Cautions
  6. 3Description
    1. 3.1 Typical Applications
    2. 3.2 Features
    3. 3.3 Connector and Test Point Description
    4. 3.4 Electrical Performance Specifications
  7. 4Test Setup
    1. 4.1 Input Supplies and LED Load Connections
    2. 4.2 Pulse Duty Cycle Limit (PLMT) Control
    3. 4.3 Analog Dimming Using IADJ
    4. 4.4 PWM Dimming Using nExt_PWM Test Points
    5. 4.5 Switching Frequency Set Point Using RON
  8. 5Performance Data and Typical Characteristic Curves
    1. 5.1 Efficiency
    2. 5.2 Analog Dimming
    3. 5.3 PWM Dimming
    4. 5.4 PWM Dimming Waveforms
  9. 6Schematic
  10. 7PCB Layout
  11. 8Bill of Materials

4.2 Pulse Duty Cycle Limit (PLMT) Control

The TPS92642-Q1 features an internal analog circuit to impose a limit on the on time, tON(LMT), and off time, tOFF(LMT), of the output current, ILED. As illustrated in Figure 4-3, the device is controlled by external UDIM pulses with widths less than tON(LMT). Any external UDIM pulses that are longer than tON(LMT) are truncated to maintain a maximum fixed duty ratio of DPLMT. The device also rejects any spurious pulses that can be present on the external UDIM input by blanking the UDIM signal during the PLMT off time. The off time is a function of the period, tPLMT, set by the external capacitor, CPLMT. The relationship between tPLMT, tON(LMT), and DPLMT is given in Equation 1.

Equation 1. t O N ( L M T ) = D P L M T × t P L M T
GUID-20220726-SS0I-F0TQ-S6SN-XDFKQPFH25NC-low.svg Figure 4-3 Duty Cycle Limit Function Using Internal Pulse Generator

This mechanism is designed to help limit overexposure to infrared lights due to error conditions in DMS applications and the internal circuitry, as shown in Figure 4-4. The ratios of RPLMT(PU) and RPLMT(PD) are tightly controlled to maintain accurate DPLMT.

GUID-20230912-SS0I-WNFQ-7MHP-LCXNLH1LH3K2-low.svg Figure 4-4 PLMT Circuit to Control Max Duty Cycle DPLMT

The desired pulse period, tPLMT, is set by external capacitor, CPLMT, as shown in Equation 2.

Equation 2. tPLMT=tON(LMT)+tOFF(LMT)tPLMT=1.168×105×CPLMT

The maximum pulse on-duration, tON(LMT), and minimum off-duration, tOFF(LMT), is given in Equation 3 and Equation 4.

Equation 3. tON(LMT)=-ln1-VPLMT_ONVCC ×RPLMT(PU)×CPLMTtON(LMT)=0.6931×RPLMT(PU)×CPLMT
Equation 4. tOFF(LMT)=-lnVPLMT_OFFVPLMT_ON ×RPLMT(PD)×CPLMTtOFF(LMT)=1.1×RPLMT(PD)×CPLMT

For LED current set point greater than 2.65 A, the maximum pulse-duration is impacted due to the switching noise in the system. The maximum pulse-duration as a function of LED current is given in Equation 5. Because the off-duration, tOFF, does not change, the duty cycle ratio reduces with increase in LED current.

Equation 5. tON(LMT)=0.6931×RPLMT(PU)×CPLMT-1.76×10-2×ILED-2.5×tPLMT

The TPS92642EVM-203 is by default setup with a PWM frequency limit of 39 Hz with a duty cycle limit of 13.6%. Testing the duty cycle control is performed by applying a PWM signal to the UDIM pin (TP3). Monitoring the PLMT circuit by using PLMT test point (TP9).

GUID-20230911-SS0I-LMH1-TFBS-S0SKWRLLVFDM-low.svgFigure 4-5 Test Point for Monitoring PLMT Circuit