Transphorm, Inc. announced that its GaN platform powers the world's first integrated photovoltaic (PV) systems from DAH Solar Co. Ltd. (Anhui Daheng New Energy Technology Co., LTD/subsidiary of DAH Solar). The PV systems are used in DAH Solar's new SolarUnit product line.

DAH Solar credits Transphorm's GaN FETs with enabling it to produce smaller, lighter, and more reliable solar panel systems that also offer higher overall power generation with lower energy consumption. The design achievements continue to demonstrate Transphorm's One Core GaN Platform, Crossing the Power Spectrum leadership position by solidifying its value proposition in the renewables market, which currently represent a GaN TAM of more than $500 million. DAH Solar uses Transphorm's 150 m and 70 m GaN FETs in the SolarUnits' design architecture (both DC-to-DC and DC-to-AC power stages).

The SolarUnits are available in three models with power outputs of 800 W, 920 W, or 1500 W and peak efficiencies of 97.16%, 97.2%, and 97.55% respectively. The GaN devices deliver higher switching frequencies and power density versus incumbent silicon solutions. Notably, the two FETs are available in PQFN88 performance packages that pair with commonly-used gate drivers-- features that helped DAH Solar quicken its design time.

Another GaN Industry FirstTransphorm supports the range of power conversion requirements (45 W to 10+ kW) across the widest range of power applications. The company's FET portfolio includes 650 V and 900 V devices with 1200 V devices in development. These FETs are JEDEC and AEC-Q101 qualified, making them optimal solutions for power adapters and computer PSUs through to broad industrial UPSs and electric vehicle mobility systems. The company's technology innovations continue to set new benchmarks across the GaN power semiconductor industry.

In parallel, they help customers bring to market new, disruptive applications in their own markets--such as DAH Solar's PV systems. These achievements are due to Transphorm's normally-off SuperGaN(R) platform, which uses the cascode d-mode configuration to harness GaN's intrinsic advantages. The superior physics of this high performance GaN platform design delivers competitively unmatched benefits such as easier drivability, easier designability, higher reliability, and greater manufacturability.