Power is not limited to the simple equation of voltage multiplied by current. From calculating the efficiency of a home appliance to determining the range of a cell tower, power measurement has a major role to play in today’s systems. this article takes you through, very briefly, the latest trends in power analysers, power meters and power supplies.
Fig 1. Power supply family from Keysight
The growing demand for energy-efficient systems in electronics industry has led to advancements in design and test engineering. There is an increasing popularity for power measurement devices across different industry verticals, such as battery-operated portable device design, UPS and motor drive manufacturing, energy STAR power measurements, consumer appliance manufacturing and lighting. Precise and fast measurement of power and related parameters is possible with today's power supplies, power meters and power analysers. Let us explore the latest technologies and innovations in the power measurement industry that have helped our design engineers to come up with better, energy-efficient products.
Trends in the industry
While power supplies are becoming extremely efficient, the need for portable designs and low-power-consump-tion designs are key driving factors in power analysis segment. Given below are the details of a few trends we find in the power measurement sector.
Faster measurement. A good measurement device responds quickly to changes in input levels, ensuring that the user gets good data even under variable conditions. Real-time measurement and analysis of power is now made possible with high-speed data delivery from the power sensors to power meters. The fast data acquisition and transfer helps in reducing the time required for measurement. This also helps make precise measurement of factors like rise time, fall time, overshoot and undershoot. Measurement speed of up to 10,000 samples per second is achieved using models like Keysight's U2040 X-series.
High accuracy. There are applications, like mobile base-station power calculation, where one should accurately measure the power; slight variations in measured data will lead to large coverage differences. Modern power meters guarantee a high-level accuracy of approximately ±0.2dB, both in lab and field. This helps in characterising the devices more precisely, to have tighter test limits and be more accurate in fixture calibration. Power analysers like Tektronix' PA4000 offer a basic accuracy of 0.05 per cent.
Fig 2. MA24105A Power Sensor-Anritsu
Auto-ranging. Auto-ranging or auto-selecting output characteristics make a power supply much more flexible than rectangular, or traditional, output characteristic power supplies because it expands the power curve, giving the user more voltage and current combinations in a single power supply. "It is like having many rectangular power supplies in one," comments Asish Jain, application engineer at Keysight Technologies. Power supplies such as Keysight's N8900 series and Tektronix' PA4000 series feature this capability.
Integrated instruments. The general trend of integrating multiple instruments into one system is also seen in the power segment. Latest test systems combine instruments like oscilloscopes, power supplies, multimeters, signal generators and data loggers into a single system. High-definition oscilloscope (HDO) with power-analyser function introduced by Teledyne LeCroy, PX8000 power scopes by Yokogawa and advanced power system (APS) family by Key-sight are examples.
Power analyser and power meter: What’s the difference?
Power meters are instruments that measure features like peak power, average power and peak-to-average ratio of RF and microwave devices with high accuracy. These are also used to calibrate other instruments and probes. These provide the user with information of power, but cannot determine the region in the frequency spectrum where the device under test is transmitting that power. This means that, even if a device passes the power meter test, it may still be transmitting at the wrong frequency. These instruments are generally used in the communication domain to measure output power of mobile phones, base stations, radar systems, etc. A high-end power meter usually has an external power sensor element, and various sensor technologies are used for this purpose.
Power analysers measure several parameters like direct current (DC), alternating current (AC), DC and AC voltage, intensity, phase rotation, apparent power, effective power, power factor and harmonics. These perform frequency domain analyses and provide both power and transmission frequency information. This helps to overcome false readings that may arise in power meters. Typical application fields include inverters, transformers, power supplies, motor drivers, lighting systems, consumer appliances and other power-conversion devices.
Power-quality measurement using oscilloscopes
Digital oscilloscopes running powerful application software for power-quality measurements can now replace traditional power meters and harmonic analysers. There are benefits of using an oscilloscope over the older toolset. While conventional power meters can overlook signal details due to their relatively slow response time, the high sampling rates of modern oscilloscopes let capture fast-changing events with great resolution. Moreover, an oscilloscope's record length is sufficient to acquire an integral number of cycles, even at a very high sampling resolution.
“Software tools let the user speed-up measurement procedures and minimise the set-up time,” says Naresh Narasimhan, country marketing manager of Tektronix India. Most power-quality measurements can be automated by full-featured power-measurement software running on the oscilloscope itself, thereby performing lengthy procedures in seconds. By reducing the number of manual calculations, it acts as a very versatile and efficient power meter. “Also, the oscilloscope probes assist in safe, reliable power measurements,” he adds.
Buying a power supply
A variety of AC and DC power sources are available in the market today, ranging from basic to complex models, with a wide range of available capabilities. Given below are a few factors to consider while buying a power supply for your applications.
V & P ratings. The first thing to consider while buying a new power supply is the voltage (V), current (I) and power (P) ratings required for your target application. Voltage of the supply should neither be too high nor too low as compared to the desired voltage value for the system you want to power. The type of voltage (AC or DC) is also very important. Another requirement is that the current rating of the power supply should be equal to (or greater than) the current necessary to run the system.
Programming capabilities and interfaces. Programmable power supplies allow the user to remotely control its operation through programming via analogue DC signal or digital interfaces like LXI, GPIB (or IEEE-488), Modbus TCP/RCU, RS-232, RS-485 and USB.
Protection. Having integrated power-protection measures help safeguard the instrument, and is very critical while testing costly systems. Over-voltage protection (OVP) and under-voltage protection (UVP) shuts down the supply when outputs are above (OVP) or below (UVP) the predefined trigger point. Over-current protection (OCP) shuts down any circuit that pulls a power higher than the power limit. There are other in-built features like over-temperature protection (OTP), overload protection (OLP), short-circuit protection (SCP) and no-load operation (NLO) available in different models.
VI quadrants. There are three types of power supplies: single-quadrant supply that has output channels capable of only sourcing current; two-quadrant supply that can source and sink current in one voltage polarity; and four-quadrant power supply that is capable of sourcing and sinking currents in both positive and negative voltages.
Speed and accuracy. The speed with which voltage output can be varied and current be measured affects the total output capacity, especially for a large production system. Some power supplies are provided with test extensions that provide high-speed reading with good accuracy, especially for viewing high-speed transient or pulse events.
Buying a power sensor
As mentioned earlier, a high-end power meter generally has an external power sensor associated with it. Due to the large variance in product offerings and specifications, a detailed comparison is the best way to evaluate power sensors before making a purchase decision. Listed below are some of the factors to consider while buying a power sensor.
1. Basic factors like frequency range, power range, dynamic range, accuracy and speed of measurement required for the potential application(s)
2. Type of power to be measured - continuous wave (CW), average or peak power
3. Pulse width, pulse repetition interval (PRI) and other pulse parameters requirement in case of pulse signals
4. Internal zero and calibration support
5. Voltage standing wave ratio (VSWR) specification
6. Triggering modes
7. PC-connectivity software and tools
Boosting efficiency and clean energy
We are seeing several initiatives across the globe with an aim to use power more efficiently - the '20-20-20' goal put forward by the European Union (EU) to reduce the present primary energy consumption by 20 per cent by the year 2020, and the transition of places like Djibouti, Tuvalu and many parts of Germany into 100 per cent energy-efficient regions, to name a few. This drive for a new, stable and affordable energy landscape, along with the changing policies, has opened up immense possibilities for the near future and has compelled many big players in the test and measurement industry to join the power sector. With such enormous trends happening in the industry, we can expect more innovations and breakthroughs in power measurement sector.
TABLE. Features of Power Measurement Devices
Device | Model | Brand | Features |
AC power supply | AC6800 | Keysight | • Intuitive user interface • Flexible I/O-LAN/LXI core and USB (standard) and GPIB (optional). Access and control the source remotely via a standard browser • Low cost of ownership |
DC power supplies | N6900 & N7900 | Keysight | VersaPower architecture: • Accelerates test-system throughput with industry-leading speed • Captures DUT's current profile with accurate measurements • Reduces ATE development time and cost with highly-integrated capabilities |
DC power supply | N8900 | Keysight | • Auto-ranging, single-output programmable DC power for ATE applications • 14 different voltages, current and power combinations available • Easily parallel units to create ‘one' power supply with >100kW of power |
HDO power analyser | HD4096 | Teledyne LeCroy | • Automatic set-up and display of relevant waveforms and parameters • Power device performance analysed in-circuit • Measurement and viewing of the time domain response of the entire control loop • Line analysis including line harmonics |
Power analyser | PA4000 | Tektronix | • Dual spiral shunt system for 0.05 per cent basic accuracy • Colour graphics display including waveforms and harmonics • Application based measurement modes and PC software |
Power scope | PX8000 | Yokogawa | • Power analyser + oscilloscope • Provides high-accuracy time based power measurement • Measures voltages up to 1000V RMS and currents up to 5A RMS (without external sensors), with a basic accuracy of ±0.1 per cent |
Power sensor | MA24105A | Anritsu | • Standalone, low-cost, plug-and-play device • Covers all major cellular and communication bands (WLL, GSM/EDGE, CDMA/ EV-DO, WCDMA/HSDPA, WiMAX and TD-SCDMA) • Broad frequency range (350MHz to 4GHz) |
Power sensor | U2040X | Keysight | • Widest dynamic range found in power sensor (-70dBm to +26dBm) • Can make both average and time-selectivity average power measurements • Four USB models for wireless and radar applications, and a dedicated LAN model for satellite testing |
The authors are from EFY Bengaluru
Authors: Anagha P. and Jai Sachith Paul