Idealphotonics' femtosecond lasers are ultrafast laser systems that generate femtosecond-level (10⁻¹⁵ s) pulse durations with terawatt-level peak power through mode-locking techniques (such as Kerr-lens mode locking), and are widely used in ultrafast spectroscopy, ophthalmic surgery, and cold processing applications.They achieve pulse generation through mode-locking techniques.

Idealphotonics' nanosecond pulsed lasers are laser systems that generate nanosecond-level (10⁻⁹ s) pulse durations with megawatt-level peak power through Q-switching techniques (such as electro-optic or acousto-optic Q-switching), and are suitable for applications such as material marking, laser cleaning, and medical aesthetics.They achieve pulse durations of 1–100 ns and megawatt-level peak power through Q-switching technology, combining high single-pulse energy (>1 mJ) with low cost, making them ideal for high-energy applications such as industrial marking and laser cleaning.

Idealphotonics' has launched a picosecond laser, an ultrashort pulse laser system that generates picosecond (10⁻¹² s) pulse widths and GW-level peak powers through mode-locking or Q-switching techniques. It is specifically designed for precision micromachining (such as cutting brittle materials) and ultrafast spectroscopy research.It generates <10 ps ultrashort pulses and GW-level peak powers through mode-locking or Q-switching techniques, possessing "cold processing" capabilities (heat-affected zone <10 μm), and is optimized for micro/nano fabrication of brittle materials and ultrafast dynamics research.