Energy Efficiency in AI Data Center With Power Testing

Energy Efficiency in AI Data Center With Power Testing Introduction Deployment of AI-based technology is happening in Data Centers, increasing focus on Energy Efficiency. Processor-intensive servers are driving up energy demands, as illustrated in the table below. The International Energy Agency (IEA) predicts that data centers will account for up...
Energy Efficiency in AI Data Center With Power Testing

Energy Efficiency in AI Data Center With Power Testing

Tektronix power rail measurement with Passive Probes (below) and Power Rail Probes (above)

Introduction

Deployment of AI-based technology is happening in Data Centers, increasing focus on Energy Efficiency. Processor-intensive servers are driving up energy demands, as illustrated in the table below. The International Energy Agency (IEA) predicts that data centers will account for up to seven percent of global electricity consumption by 2030, a number equivalent to the entire country of India’s electricity consumption. Power Integrity Testing is crucial in managing and optimizing Energy Efficiency amid this growing demand.

CPU/GPU TechnologyCurrentImpedanceWatts (Cabinet Avg)
Today’s non-AI Server CPU400 A100 µΩ25 kW
Early AI GPU’s800 A50 µΩ75 kW
Latest AI GPU1,400 A28 µΩ110 kW
Next Gen GPU2,000 A20 µΩ500 kW-1MW

Figure 1: Power Consumption of CPU & GPU technology in Data Center.

With this growing demand for power, the emphasis on energy efficiency is critical. Partnering with Steve Sandler, a highly-recognized power integrity expert; Tektronix has developed good measurement techniques to improve Operations/Watt of next generation AI Data Centers.

Improving Power Delivery Network (PDN) Energy-Efficiency

PDNs must provide many low-noise DC power rails for sensitive loads driving the GPU’s in these server racks. The quest for more speed and higher density means faster edge rates, higher frequencies and more rails, but at lower voltage levels and higher currents as illustrated above. This puts emphasis on good power integrity.

The goal of making power integrity measurements is to validate that the voltage and current reaching the Point of Load (POL) meet the load’s power rail specifications under all expected operating conditions. Special attention is required to accurately measure millivolts of power rail noise at GHz frequencies.

Let’s take a look at how to assess PDN performance with a high-level view of a power distribution network on a server-based system.

Diagram of DC power flow from supply to server racks, highlighting voltage regulators for CPU, GPU, and memory
Figure 2: High Level Power Distribution Network in the Data Center.

As shown here, typical data centers supply power to their AI-based servers via a 12, 24, or 48 V DC supply. This power is then converted to other supply voltages on the motherboard. Engineers need to analyze every link in the chain, from supply output to FPGAs, processors, and other complex ICs. Effective management of power rail impedance at very low levels is essential to deliver the high currents demanded by AI-centric servers driven by GPU technology.

Impedance management is complex because the network includes multiple components such as voltage regulators, decoupling capacitors, and PCB traces. Additionally, high-speed switching and hot-swappable server cards introduce unexpected impedance variations. These fluctuations can result in excessive transients or noise, impacting overall system stability.

Ensuring a stable, energy-efficient design starts by minimizing noise in the PDN. Noise specifications on power rails can go up into MHz or GHz frequency ranges with amplitudes in millivolts.

Assessing for energy-efficiency starts with making power quality measurements on the AC line inputs and outputs to ensure line voltage and line current. Measurement values to assess quality are shown below:

  • Frequency
  • RMS voltage and current
  • Impedance
  • Crest Factor (voltage and current)
  • True, reactive, and apparent power
  • Power factor and phase

To ensure these measurements are made accurately; oscilloscope probe selection is important; using a differential probe to measure the line voltage of the system and a current probe to measure the line current of the system.

Another critical measurement is to perform Frequency Response Analysis of the PDN’s control loop response. This will provide valuable information about the speed of the control loop and stability of the power supply. A Bode plot is used to view the analysis, and here is an example setup in Figure 3.

Diagram of impedance measurement setup using power rail probes for high accuracy in Data Center design
Figure 3: Measurement setup for Impedance in a Power Distribution Network.

Power Integrity Probing Systems Deserve Attention

The high-impedance 10X passive probes that come with today’s oscilloscopes may have enough bandwidth, but they attenuate the very noise signal you’re trying to measure. 1X probes pass the noise signal without attenuation, but they are limited to several MHz bandwidth. Transmission line probes or cables with 50 Ω input impedance offer great high-frequency performance but cause significant loading at DC, unless a DC Block is added.  Attenuating transmission line probes offer less loading while maintaining low noise and high bandwidth.

Power Rail Probes are another category of probes that provide low noise and high offset range at up to 4 GHz with DC offset ranging from -60 to +60 Vdc. This is seen as a more accurate alternative to traditional Passive Probes in identifying sources of noise; as shown below in Figure 4. Depending on the voltage of the power rail, a DC block might be required.  If this is the case, be sure it offers inrush protection for the oscilloscope and that isn’t DC or AC bias sensitive. Power rail probes, while very low noise, are also single ended.  To assist, look for coaxial isolators that further minimize measurement ground loop errors. Picotest offers a selection of DC Blocks and Coaxial Isolators to support these needs.  Learn more about the Ultimate Power Rail Noise Measurement.

Tektronix power rail measurement with Passive Probes (below) and Power Rail Probes (above)
Figure 4: A comparison of power supply line measurements of ripple with a passive probe (below trace) and power rail probe (above trace). See the difference?

Fast, low-noise acquisitions combined with ultra-fast-edge loads emulate AI-level processor workloads; allowing for an accurate assessment of power rail noise voltage and power-rail to power rail crosstalk on PDN designs. Combined with either a Tektronix 5 Series B MSO or 6 Series B MSO oscilloscopes; Picotest offers a complete line of loads up to 2,000 amps, 1ns edge loads supporting a sample rate of up to 65MS/s for accurate emulation efforts. (see Figure 5)

Oscilloscope screen showing accurate high voltage signal, highlighting low noise measurement importance
Figure 5. A characterization showing a pseudorandom step of a high-amplitude load for AI-level processor. Accuracy in this characterization is enabled using Picotest loads and measured by a Tektronix 6 Series B MSO oscilloscope, ideal for low-noise and high-resolution signal capture.

Oscilloscope Measurement Analysis Saves Time, Reduces Errors

Identification and analysis of trouble spots in a PDN can take time. Looking for ripple, overshoot, under-shoot, turn-on, turn-off, time-trend, settling time, and jitter in a power delivery network is a complex undertaking. Thankfully, most of today’s modern oscilloscopes provide built-in analysis software to setup the instrument & automate the signal acquisition and display. Below is an example showing an automated measurement of ripple. Having this built-in to the instrument and capable of being automated from a remote PC simplifies large team efforts to evaluate AI-enabled performance over time and temperature variants to stress the efficiency and durability of the server.

Oscilloscope screen showing Ripple measurements on a Power Delivery Network for energy-efficiency
Figure 6: Automated Ripple Measurement with annotation results in right side of a 5 Series B MSO Oscilloscope display.

Summary

With artificial intelligence (AI) driving up the energy demand on next-generation data centers; it is becoming more critical than ever to assess the performance and efficiency of the power delivery network.

Having a good test and measurement strategy for PDN evaluation will lead to an optimally functioning, AI-ready data center in terms of performance, reliability and energy efficiency.

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