SLUSDS3A March 2020 – January 2024 UCC21739-Q1
PRODUCTION DATA
A typical application circuit is shown in Figure 8-11. To sense temperature, the AIN pin is connected to the thermal diode or thermistor which can be discrete or integrated within the power module. A low pass filter is recommended for the AIN input. Since the temperature signal does not have a high bandwidth, the low pass filter is mainly used for filtering the noise introduced by the switching of the power device, which does not require stringent control for propagation delay. The filter capacitance for Cfilt can be chosen between 1nF to 100nF and the filter resistance Rfilt between 1Ω to 10Ω according to the noise level.
The output of APWM is directly connected to the microcontroller to measure the duty cycle dependent on the voltage input at AIN, using Equation 13.
When a high-precision voltage supply for VCC is used on the primary side of UCC21739-Q1 the duty cycle output of APWM may also be filtered and the voltage measured using the microcontroller's ADC input pin, as shown in Figure 8-12. The frequency of APWM is 400kHz, so the value for Rfilt_2 and Cfilt_2 should be such that the cutoff frequency is below 400kHz. Temperature does not change rapidly, thus the rise time due to the RC constant of the filter is not under a strict requirement.
The example below shows the results using a 4.7kΩ NTC, NTCS0805E3472FMT, in series with a 3kΩ resistor and also the thermal diode using four diode-connected MMBT3904 NPN transistors. The sensed voltage of the 4 MMBT3904 thermal diodes connected in series ranges from about 2.5V to 1.6V from 25°C to 135°C, corresponding to 50% to 68% duty cycle. The sensed voltage of the NTC thermistor connected in series with the 3kΩ resistor ranges from about 1.5V to 0.6V from 25°C to 135°C, corresponding to 70% to 88% duty cycle. The voltage at VAIN of both sensors and the corresponding measured duty cycle at APWM is shown in Figure 8-13.
The duty cycle output has an accuracy of ±3% throughout temperature without any calibration, as shown in Figure 8-14 but with single-point calibration at 25°C, the duty accuracy can be improved to ±1%, as shown in Figure 8-15.