ZHCSLK6A July 2021 – December 2021 TPS1HC100-Q1
PRODUCTION DATA
Figure 8-5 shows the typical set up for a capacitive load application and the internal blocks that function when the device is used. Note that all capacitive loads have an associated load in parallel with the capacitor that is described as a resistive load but in reality it can be inductive or resistive.
The second key care about for this application is to make sure that the capacitive load can be charged up completely without the device hitting thermal shutdown. The reason is because if the device hits thermal shutdown during the charging, the resistive nature of the load in parallel with the capacitor starts to discharge the capacitor over the duration the TPS1HC100-Q1 is off. Note that there are some application with high enough load impedance that the TPS1HC100-Q1 hitting thermal shutdown and trying again is acceptable; however, for the majority of applications, the system must be designed so that the TPS1HC100-Q1 does not hit thermal shutdown while charging the capacitor.
With the current clamping feature of the TPS1HC100-Q1, capacitors can be charged up at a lower inrush current than other high current limit switches. This lower inrush current means that the capacitor takes a little longer to charge all the way up. The time that it takes to charge up follows the equation below.
For more information about capacitive charging with high side switches, see the How to Drive Capacitive Loads application note application note. This application note has information about the thermal modeling available along with quick ways to estimate if a high side switch is able to charge a capacitor to a given voltage.