Texas Instruments TLV62090EVM-125 Evaluation Module TLV62090EVM-125 TLV62090EVM-125 Datenbogen
Produktcode
TLV62090EVM-125
Test Summary
Connect the meters, scope probes (see
), 2-
Ω
output load, shunt jumpers, and input power supply
(
); set the oscilloscope to 200 ns/div, positive trigger, or HF trigger on CH2; CH1: ac-coupled, 50
mV/div; CH2: dc-coupled, 2 V/div; CH3: ac-coupled, 10 mV/div; CH4: dc-coupled, 10 V/div. Users can
replace the resistive load with a system load or decade load box to vary the load (2-
replace the resistive load with a system load or decade load box to vary the load (2-
Ω
to 25-
Ω
load).
Figure 1. EVM Schematic and Evaluation Setup
3.3
Test Procedure
1. Set up the EVM according to
and
, and preset the power supply 4.5 Vdc at
approximately 2.5-A current limit.
2. Turn on input supply, and verify that the input voltage is approximately 4.5 Vdc (DMM#1) and the
output voltage is at approximately 1.8 Vdc (DMM#2).
3. Refer to
, and verify that the duty cycle is near 40%, input ripple is less than 50 mVpp
(ignoring switching spikes) and the output ripple is less than 10 mVpp. These waveforms were taken
with high-frequency probes (meaning that the ground lead was short (approximately 1 cm). This
reduces the high-frequency spikes that the ground loop on the probe picks up.
with high-frequency probes (meaning that the ground lead was short (approximately 1 cm). This
reduces the high-frequency spikes that the ground loop on the probe picks up.
4. Vary input voltage between 2.6 V and 5.5 V, and observe the change in duty cycle and ripple
waveforms. Set Vin back to 4.5 Vdc.
5. Change the output load to 25
Ω
, set CH3 to 50 mV/div, and verify how the duty cycle changes into a
burst low-power mode (see
). At the end of the burst switching, the inductor’s current goes to
zero, becomes discontinuous, and rings with the FET and output capacitance (normal operation at light
loads). Set the load back to approximately 2
loads). Set the load back to approximately 2
Ω
.
6. Turn off the input supply. Set CH1 to dc coupled, 2 V/div; set CH3 to dc coupled, 1 V/div; CH4 to dc
coupled, 5 V/div; set the oscilloscope timing to 500 µs/div; set the oscilloscope trigger to positive or HF
trigger on CH1 and arm scope. Turn on the laboratory supply. The laboratory supply that captured
trigger on CH1 and arm scope. Turn on the laboratory supply. The laboratory supply that captured
ramped up over 3 ms.
is a hot plug power up. The output ramp rate is the same in
both figures due to the controlled soft-start. The user can program the output to track another voltage
with the soft-start pin. See the data sheet for more details.
with the soft-start pin. See the data sheet for more details.
7. Move CH1 to JP1-2 (Enable pin), and set JP1 shunt to off. Arm the oscilloscope, and remove JP1
shunt.
shows the power up of the converter by the enable pin.
8. Set the oscilloscope trigger to negative, arm the oscilloscope, and apply a shunt on JP1-OFF. See
for the power-down sequence.
9. With an understanding of the basic functions of the EVM, users may want to integrate the EVM into
their system using short, twisted wires, to minimize connection impedances.
3
SLVU693B – March 2012 – Revised May 2012
TLV62090EVM-125 Evaluation Module
Copyright © 2012, Texas Instruments Incorporated