Views: 5 Author: Site Editor Publish Time: 2022-06-07 Origin: Site
XM-power innovation meets GaN technology XM-power was one of the first companies to design chargers for mobile devices and has been a trusted name since those earliest days. GaN technology is only part of the story. We work closely with industry leaders to develop robust, faster, and safer products for each device you'll be connecting. The world-class research and development we're known for extend to our GaN chargers family. In-house mechanical work, innovative electrical designs, and partnerships with leading chipset manufacturers deliver the best products and user experience possible.
GaN is different. It's a crystal-like material that's capable of conducting far higher voltages. Electrical current can pass through components made from GaN faster than silicon, which leads to even faster processing. GaN is more efficient, so there's less heat.
Silicon has been the preferred material for transistors since the 1980s. Silicon absorbs energy better than traditionally used materials, such as vacuum tubes, while lowering costs due to its low production cost. Technology advancements have resulted and quickly changed the future of chargers. GaN is a unique material. It's a crystal-like substance that can conduct even higher voltages. GaN components allow electrical current to flow through them more quickly.
For now, GaN is an excellent choice of materials for chargers and power banks, thanks to its properties. Many companies have embraced the new technology and rolled out products based on GaN.
Heat is a significant factor in determining how long electronic devices keep working, and chargers are no exception. The efficiency of GaN in transferring power keeps heat to a minimum, so a modern GaN charger will keep working for a lot longer than non-GaN chargers made even a year or two in the past.
GaN replaces silicon. Since the '80s, silicon has been the go-to material for transistors. Silicon conducts electricity better than previously used materials—such as vacuum tubes—and keeps costs down, as it's not too expensive to produce. Over the decades, improvements to technology led to the high performance we're accustomed to today. Advancement can only go so far, and silicon transistors may be close to as good as they will get. The properties of silicon material itself as far as heat and electrical transfer mean the components can't get any smaller. GaN is different. It's a crystal-like material that's capable of conducting far higher voltages. Electrical current can pass through components made from GaN faster than silicon, which leads to even faster processing. GaN is more efficient, so there's less heat.
The most efficient power Being lightweight and occupying less space makes GaN chargers great for travel. One charger is all most people will need when it has enough power for everything from a phone to a tablet and even a laptop. Heat is a significant factor in determining how long electronic devices keep working, and chargers are no exception. The efficiency of GaN in transferring power keeps heat to a minimum, so a modern GaN charger will keep working for a lot longer than non-GaN chargers made even a year or two in the past.
Digital devices have evolved over the years. With a focus on improved user experience, changes in design, size, display, and more have led to the production of newer and better devices. However, one lingering problem has been battery life. As a result, an increase in battery volume became inevitable. This solution came with a new challenge, charging time. This solution did not end battery problems as charging time became an issue. The need for a shorter charging time led to the emergence of fast charging protocols. High-power fast charging has become the norm for digital devices.