TRI-DIODE FOR LASER THERAPY AND TRI-DIODE-BASED EQUIPMENT FOR USE IN LASER THERAPY, this invention patent application proposes a tri-diode used to generate a particular type of laser that can be used to treat all types of cellular lesions, both in humans and in other animals. The invention can be applied to any age of patient and any lesion condition. The tri-diode proposed generates a laser from a combination of three specific molecules, namely: zinc, phosphorus or phosphate and aluminum; it is used to encourage cell regeneration, having a useable power of between 1.2 W and 1.5 W in each diode and a total power of between 3.6 W and 4.5 W, with a wavelength of between 780 and 808 nm; the zinc, phosphorus or phosphate and aluminum molecules can be combined in up to 26 mixtures.

Some embodiments include a method. The method can include: providing a carrier substrate; forming a first device material over the carrier substrate; and after forming the first device material over the carrier substrate, transforming the first device material into a second device material. Meanwhile, the transforming the first device material into the second device material can include: causing a cationic exchange in the first device material; and causing an anionic exchange in the first device material. The causing the cationic exchange in the first device material and the causing the anionic exchange in the first device material can occur approximately simultaneously. Other embodiments of related methods and systems are also disclosed.

According to one embodiment, a semiconductor laser includes a semiconductor laser element. A drive current which is composed of a direct current and an alternating current superposed thereon is applied to the semiconductor laser element. A waveform of the alternating current is a non-square wave. A frequency of the alternating current is from 50 Hz to 500 kHz.

A light sensing system includes a plurality of light-emitting devices arranged to have a first optical axis and a plurality of light-receiving devices arranged to have a second optical axis, the second optical axis being parallel with the first optical axis. The plurality of light-emitting devices and the plurality of light-receiving devices are formed to have a monolithically integrated structure, and the first optical axis and the second optical axis are substantially coaxial to each other, thus improving the efficiency of light reception.

An optoelectronic component includes a layer structure including an active zone that generates electromagnetic radiation, wherein the active zone is arranged in a plane, the layer structure includes a top side and four side faces, the first and third side faces are arranged opposite one another, the second and fourth side faces are arranged opposite one another, a strip-type ridge structure is arranged on the top side of the layer structure, the ridge structure extends between the first side face and the third side face, the first side face constitutes an emission face for electromagnetic radiation, a first recess is introduced into the top side of the layer structure laterally alongside the ridge structure, a second recess is introduced into the first recess, and the second recess extends as far as the second side face.

According to one embodiment, a semiconductor laser includes a semiconductor laser element. A drive current which is composed of a direct current and an alternating current superposed thereon is applied to the semiconductor laser element. A waveform of the alternating current is a non-square wave. A frequency of the alternating current is from 50 Hz to 500 kHz.

Some embodiments include a method. The method can include: providing a carrier substrate; forming a first device material over the carrier substrate; and after forming the first device material over the carrier substrate, transforming the first device material into a second device material. Meanwhile, the transforming the first device material into the second device material can include: causing a cationic exchange in the first device material; and causing an anionic exchange in the first device material. The causing the cationic exchange in the first device material and the causing the anionic exchange in the first device material can occur approximately simultaneously. Other embodiments of related methods and systems are also disclosed.