SLVAFH6 November   2023 LM25066 , LM5066 , LM5066I , TPS25984 , TPS25985 , TPS25990 , TPS536C9T

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1Introduction
  5. 2What are PSYS™ and PSYS_CRIT#™?
  6. 3Implementation of PSYS Monitor
    1. 3.1 Existing Designs
    2. 3.2 Proposed Designs
  7. 4ISYS Resistor (RISYS) and Gain (ISYS_IN_GAIN) Selection in TPS536C9T VR14 Controller
    1. 4.1 Steps to Calculate the Value of RIMON or RISYS and ISYS_IN_GAIN
    2. 4.2 Design Example
  8. 5Functional Verification of PSYS and PSYS_CRIT# in TPS536C9T VR14 Controller Using TPS25984, TPS25985, or TPS25990 eFuses as PSYS Monitor
  9. 6Extraction of Platform Current Information With Multiple PSYS Monitors Connected to the Same PSU
    1. 6.1 Designing the Non-Inverting Summing Amplifier
    2. 6.2 Design Guideline and Example
  10. 7Summary
  11. 8References

3.2 Proposed Designs

Integrated FET-based hot swap designs, subsequently called eFuses, are commonly used in input power path protections for high-current enterprise server power supply designs because of improved power density and cost competitiveness. TI released the TPS25984, TPS25985 (both without PMBus® interface), and TPS25990 (with PMBus® interface) eFuses in the aforementioned market space.

In addition to providing several input power path protection features, these three eFuses allow the systems to monitor the output load current accurately by providing an analog current output (IMON) on the IMON pin. IMON is proportional to the current through the FET inside the eFuse. This IMON output is fed to the ISYS pin to implement PSYS™ in the VR14 controller, as shown in Figure 3-4.

GUID-20231009-SS0I-FVLM-QT7V-XMTGX6VPD46C-low.svgFigure 3-4 PSYS Monitor Functionality Implemented Using TPS25984, TPS25985, or TPS25990 eFuses

The benefit of having a current output is that the signal can be routed across a board without adding significant errors due to voltage drop or noise coupling from adjacent traces. The current output also allows the IMON pins of multiple eFuse devices in a parallel configuration to be tied together to get the total current. As shown in Figure 3-5, the IMON signal is fed to the ISYS pin of the VR14 controller and is converted to a voltage by dropping it across a resistor (RISYS or RIMON) close to the VR14 controller to implement the PSYS™. The current monitoring circuit inside these three eFuses is designed to provide high bandwidth (> 500 kHz) and high accuracy (<± 1.5%) across load and ambient temperature conditions, irrespective of board layout and other system operating conditions. This helps in achieving the required response time (10 μs) and error specifications (± 2%) for PSYS™ implementation. The analog current monitoring response of these eFuses is depicted in Figure 3-6 to demonstrate the large signal bandwidth of IMON. There is no need to add any external components to implement the PSYS monitor in the design.

GUID-20231009-SS0I-R5WQ-QBKW-CSDSS34XJXBH-low.svgFigure 3-5 Parallel Connection: TPS25984, TPS25985, and TPS25990 eFuses
Note: The input power path protection design using TPS25984, TPS25985, or TPS25990 eFuses itself provides the functionality of the PSYS monitor by accomplishing the required large-signal bandwidth and accuracy criteria to implement PSYS™ functionality in the VR14 controllers.
GUID-20231009-SS0I-WNQP-1NGJ-8BBL8QCWDW0H-low.svgFigure 3-6 Large-Signal Current Monitoring Bandwidth of TPS25984, TPS25985, or TPS25990 eFuses