SLUAB19 May   2025 LM25180-Q1 , LM5155-Q1 , SN6507-Q1 , UCC14240-Q1

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1Introduction
    1. 1.1 Low-Voltage Isolated Bias Power Supply
    2. 1.2 High-Voltage Bias Power Supply
  5. 2Centralized Isolated Bias Power Supply Architecture
  6. 3Semi-Distributed Isolated Bias Power Supply Architecture
  7. 4Bias Power Supply Using DC-DC Converter Module
  8. 5Isolated Bias Power Supply Using Gate Driver to Drive the Transformer
  9. 6Redundancy in the Isolated Bias Power Supply Architecture
  10. 7Summary
  11. 8Terminology

4 Bias Power Supply Using DC-DC Converter Module

Use of an integrated DC-DC transformer module can be the preferable choice for a distributed type of architecture. These integrated modules have an integrated transformer, which is switching at a very high frequency range of 11MHz to 15MHz. Using an integrated transformer module eliminates the need of external transformers, which results in a reduction in size and height of the overall system. An integrated transformer provides higher robustness to vibration. Additionally, these integrated DC-DC modules need only a few external discrete components; therefore, this architecture is simpler from the design and layout perspective.

TI offers several variants of the integrated DC-DC modules. These variants give the flexibility to choose the appropriate device, based on the availability of the input voltage rail in the system and required output voltage. Table 4-1 shows all variants and the technical specifications.

Table 4-1 Texas Instruments Integrated Transformer Designs
Part Number Isolation Strength VIN | VOUT Nominal VIN Range VOUT Range Typical Power
UCC14240-Q1
UCC14241-Q1		 Basic (3kVRMS)
Reinforced (5kVRMS)		 24VIN | 25VOUT, 21V–27V 15V–25V 2.0W
UCC14140-Q1
UCC14141-Q1		 Basic (3kVRMS)
Reinforced (5kVRMS)		 12VIN | 25VOUT 10.8V–13.2V
8V–18V		 15V–25V
15V–25V		 1.5W
1.0W
UCC14340-Q1
UCC14341-Q1		 Basic (3kVRMS)
Reinforced (5kVRMS)		 15VIN | 25VOUT 13.5V–16.5V 15V–25V 1.5W
UCC14130-Q1
UCC14131-Q1		 Basic (3kVRMS)
Reinforced (5kVRMS)		 12–15VIN |
12–15VOUT		 12V–15V
10V–18V
15V–18V
14V–18V		 12V–15V
10V–12V
15V–18V
10V - 18V		 1.5W
1.0W
1.5W
1.0W
UCC15240-Q1
UCC15241-Q1		 Basic (3kVRMS)
Reinforced (5kVRMS)		 24VIN | 25VOUT 21V–27V 15V–25V 2.5W

The requirement of the pre-regulator to provide a regulated voltage rail to the integrated DC-DC modules depends on the power requirement of the isolated gate drivers. As mentioned in Table 4-1, there is power derating in case of a wide input voltage range while connecting the integrated DC-DC module directly with the battery.

As Figure 4-1 shows, a separate integrated DC-DC module is used for each high-side gate driver. Whereas, the low-side gate drivers are supplied using a single integrated DC-DC module. For the low side, it is possible to use same integrated DC-DC module to supply bias power to multiple gate drivers that share the same ground. Depending on the total required power needed for two low side isolated gate drivers, those are powered using a single integrated DC-DC module device, a higher power rated variant can be preferred.

Bias Power Supply Architecture Using DC-DC Modules Figure 4-1 Bias Power Supply Architecture Using DC-DC Modules

Isolated bias power supply for the high side can be done using the bootstrap approach. As Figure 4-2 shows, isolated bias power for high-side gate drivers is generated using the bootstrap circuit. In the case of using a DC-DC module, each DC-DC module can be used to supply the low side directly and the high side using bootstrap. Other topologies like flyback, push-pull, and so forth, can be also be realized using the bootstrap approach. For a design with high switching frequency, especially in case of use of GaN switches, the power loss in the bootstrap diode can lead to thermal challenges. Therefore, the bootstrap approach can be desirable in the case of low switching frequency designs only.

Bias Power Supply Architecture Using Bootstrap Approach Figure 4-2 Bias Power Supply Architecture Using Bootstrap Approach