Batteries power the world around us—from the devices in our hands to the life-saving equipment we rely on daily. Ever notice that your electronics arrive with a small charge? That's because batteries undergo charge and discharge testing before reaching the market. This is where battery cyclers come in—they are essential tools that test a battery’s performance, ensuring it meets reliability and efficiency standards.
A battery cycler is a testing instrument that repeatedly charges and discharges a battery under controlled electrical conditions. This cycling process shows how a battery performs, how it ages, and how it responds to real-world electrical demands. Labs use cyclers across R&D, validation, quality control, and production environments due to their versatility, helping ensure batteries meet performance and safety standards before going to market.
Battery cyclers track a range of performance indicators that help engineers understand overall battery health. These include:
Together, these measurements reveal how a cell behaves over time, whether it’s safe to operate under different loads, and whether it meets the requirements of its intended application, whether that’s consumer electronics, wearables, EV batteries, energy-storage systems, or other battery types.
Choosing a battery cycler is the first step in your battery testing process is what you learn in our previously published guide, "How to purchase a battery test chamber" buyers guide. Since the cycler determines your current requirements and the number of channels you'll need, making this decision early helps you avoid wasted channels, saving both time and money when working with a test chamber manufacturer. Purchasing a test chamber without fully understanding your cycler could lead to missed potential—software integration issues, wasted channel space, and higher upfront costs if you need more chambers to fulfill your testing requirements. At AES, our battery test chambers offer a unique, secure location for cycler connection located at the back of the chamber called the ATP Cycler interface. This ensures connections, adequate safety, and functionality for direct communication about the health of your cell.
Battery cyclers work by applying controlled charge and discharge patterns to a battery and measuring how it responds at every stage. This process simulates real use in a repeatable way so engineers can study performance, aging, and safety under different electrical conditions.
Most systems rely on a few standard control modes. The two most common are constant current (CC) and constant voltage (CV), with many tests combining both in a CC–CV profile (especially for lithium-ion batteries). Cyclers can also run pulse or dynamic profiles that mimic fast charging, power spikes, or the stop-and-start behavior found in wearables, EVs, and other high-demand applications.
As the battery moves through these cycles, the cycler continuously collects data. Engineers track how voltage, current, and other test parameters change over time, along with trends in efficiency, internal resistance, and thermal behavior. When sensors or an environmental chamber are added to the setup, teams can also monitor temperature effects, which often reveal issues that don’t show up at room temperature.
Together, all of these measurements give a clear, precision-focused picture of how the battery performs day-to-day, how quickly it loses capacity, and how it responds to different load conditions. Cyclers with more advanced features add capabilities like custom waveforms, synchronized sensor inputs, and software tools that help model specific use cases or long-term aging scenarios.
Battery cyclers and environmental test chambers are most effective when they’re treated as a single testing system rather than separate pieces of equipment. The cycler controls the electrical load (charging, discharging, and measuring performance) while the chamber manages temperature conditions that directly influence how the battery behaves. Pairing the two lets teams capture complete, accurate test data that reflects real-world operating environments.
Choosing your battery cycler early in the process is an important first step. The cycler defines your current requirements, voltage range, and the number of channels you’ll need, and these decisions directly affect the chamber you select. Without that information upfront, it’s easy to run into issues such as wasted channels, mismatched throughput, or software integration gaps that slow down your testing workflow.
Together, the cycler and chamber make testing easier and more reliable in several ways:
Using an integrated test chamber and battery cycler system also creates a smoother installation, more predictable results, and a more efficient testing workflow. It ensures you’re getting the full value out of both pieces of equipment—electrically, thermally, and operationally.
EVs are leading the charge into the automotive future, and with proper battery cyclers and chambers, the industry will reach its goals. With the support of battery testing, an EV business can test the true capabilities of their batteries—regardless of the format. Given that the cycler and battery test chamber work hand in hand, test data can provide insight into how the battery will perform on its single charge. EV manufacturers are always looking for new battery chemistries that can be tested to shorten the battery charge life and produce a longer driving range; all of this is done utilizing a test chamber.
The consumer electronics industry depends on accurate testing to produce new products. For example, a consumer electronics business may look to test the ability of a smart wearable’s super capacitor. By leveraging a battery chamber and effective cycler, it is possible to determine if the super capacitor fits its purpose (according to its corresponding pulse output). Since wearable devices are on the rise, these products must go through rigorous testing as these devices can be worn on consumers' wrists, ears, and faces. You must ensure the highest quality to ensure safety for your consumers. The results ensure that only the highest quality batteries reach the market, helping to protect your brand reputation.
Energy Storage Systems rely on larger-format batteries and module configurations that cycle daily, usually under demanding environmental conditions. Battery cyclers help teams measure capacity retention, efficiency, and long-term stability, all critical factors for grid reliability and peak-demand performance. When these tests are paired with temperature control, engineers can simulate outdoor conditions, daily cycling patterns, and long-duration storage behavior to ensure consistent performance over years of operation.
Bringing together the right battery cycler and a well-matched environmental chamber sets the foundation for reliable, repeatable testing. AES has decades of experience helping teams build these integrated setups so they can move from installation to testing with confidence.
Our battery test chambers are designed to work smoothly with nearly any cycler brand, and our ATP interface makes cable routing and integration straightforward. From planning and configuration to onsite setup, our engineers and technicians work directly with your team to ensure your testing system is safe, efficient, and ready for long-term use.
To further simplify integration, AES also offers the FUSION series. Every FUSION system is pre-integrated, validated, and ready for immediate deployment. For over a decade, AES and MACCOR have worked together to deliver integrated battery testing solutions, and that partnership is now built into every FUSION system bringing the reliability of two proven U.S. manufacturers into a single, unified solution.
If you’re building or expanding your battery testing program, we’re dedicated to a long-term partnership with you to guarantee testing success and full integration. Contact a sales engineer today to learn more about the relationship between our wide variety of battery test chambers and cyclers.
A battery cycler is used to charge and discharge a battery under controlled conditions while measuring how it performs. Cyclers help engineers study capacity, efficiency, aging, internal resistance, and safety behavior.
Cycling a battery means repeatedly charging and discharging it to see how it responds over time. This process shows how much capacity the battery can deliver, how quickly it ages, and whether it performs safely under load.
Most battery cyclers can be paired with an environmental test chamber as long as the chamber supports proper cable routing, safety requirements, and power needs. Many battery test chambers especially AES chambers are designed to work with a wide range of cycler brands. AES even has a series with a cycler already ergonomically connected. The FUSION series.
Key features to look for include:
The current and voltage range—including the maximum current—your tests require
The number of channels you need for throughput
Support for CC, CV, and combined CC–CV profiles
Data accuracy and sampling rate
Safe, organized cable connections and advanced safety features
Software that allows custom test profiles and clear data export
These factors determine how flexible and reliable your testing program will be.
Cycling time depends on the battery’s capacity, the charge and discharge rates, and the test profile. A single cycle can take anywhere from under an hour to several hours. Long-term tests that run hundreds of cycles may take days or weeks.
Yes, a cycler for battery testing tracks how capacity, efficiency, and internal resistance change over repeated cycles. This data shows how the battery ages and helps estimate its usable life in real-world applications.