Certifications

iso9001
iso14001
icas
Delivery
security
warranty
roiginal
RoHS
UL
Millionen elektronischer Teile auf Lager. Preis- und Vorlaufzeitangebote innerhalb von 24 Stunden.

The first chip to integrate both laser and photonic waveguide

Jan 11 2024 2024-01 Semiconductors 3M
Article Cover
The first chip to integrate laser and photonic waveguide at the same time is a new optoelectronic integrated circuit technology, which can integrate laser and photonic waveguide on the same chip to realize the transmission and transmission of optical signals. The research and development of this chip has important scientific significance and application value, and can play an important role in communication, computing, optical sensing and other fields.

The first chip to integrate laser and photonic waveguide at the same time is a new optoelectronic integrated circuit technology, which can integrate laser and photonic waveguide on the same chip to realize the transmission and transmission of optical signals. The research and development of this chip has important scientific significance and application value, and can play an important role in communication, computing, optical sensing and other fields.

A laser is a device that produces a highly focused beam of light that converts light energy into a laser beam. Photon waveguide is an optical device that transmits optical signals through the chip, and can transmit optical signals inside the chip. Traditionally, lasers and photon waveguides are made separately, and then the optical signal is transmitted through an external connection. However, this method has many problems, such as signal loss, unreliable connection and so on. Therefore, it is of great significance to develop a chip that integrates laser and photonic waveguide simultaneously.

The development of the first integrated laser and photonic waveguide chip needed to solve several key technical problems:

1, material selection and preparation: the laser needs to have high optical quality and high optical response speed, and the photon waveguide needs to have low loss and high optical transmission efficiency. Therefore, it is necessary to select suitable materials and prepare materials with good optical properties.

2, the design and preparation of photon waveguide: photon waveguide is the key device that transmits the optical signal to the inside of the chip, and it is necessary to design a suitable waveguide structure and prepare a photon waveguide with good optical performance.

3, laser design and preparation: laser is the key device to produce laser beam, need to design a suitable laser structure, and prepare a laser with high power and high efficiency.

4, the integration of photon waveguide and laser: the integration of photon waveguide and laser on the same chip needs to solve the coupling and transmission problems of optical signals, and it is necessary to design a suitable coupling structure and achieve reliable optical signal transmission.

The development of the first chip to integrate both laser and photonic waveguide required not only the above technical issues to be solved, but also rigorous testing and validation. Through the verification of experiments and practical applications, the performance and reliability of the chip can be evaluated, and the design and preparation process of the chip can be further optimized and improved.

The integrated laser and photonic waveguide chip has a wide application prospect. In the field of communication, high-speed and large-capacity optical communication can be achieved to improve communication speed and bandwidth. In the field of computing, optical transmission and light processing can be achieved to improve computing speed and energy efficiency. In the field of optical sensing, high sensitivity and high resolution optical sensing can be achieved to improve the sensing performance and accuracy. Therefore, the development of the first integrated laser and photonic waveguide chip has important scientific significance and application value.

Die Produkte, an denen Sie interessiert sein könnten

EP3000AC48IN EP3000AC48IN AC/DC CONVERTER 52V 3000W 5580

More on Order

SW003A5F961 SW003A5F961 DC DC CONVERTER 3.3V 12W 5256

More on Order

ATH016A0X43Z ATH016A0X43Z DC DC CONVERTER 0.8-3.6V 58W 8262

More on Order

QW050F1 QW050F1 DC DC CONVERTER 3.3V 33W 5688

More on Order

QW010A0A1 QW010A0A1 DC DC CONVERTER 5V 50W 5436

More on Order

JRW040A0A41 JRW040A0A41 DC DC CONVERTER 5V 200W 7092

More on Order

QSVW035A0B41Z QSVW035A0B41Z DC DC CONVERTER 12V 420W 2250

More on Order

PIM300FZ PIM300FZ DC DC CONVERTER -48V 300W 7236

More on Order

CY62157DV30LL-55BVXAT CY62157DV30LL-55BVXAT IC SRAM 8M PARALLEL 48VFBGA 3222

More on Order

CY62157DV30L-55BVXET CY62157DV30L-55BVXET IC SRAM 8M PARALLEL 48VFBGA 5436

More on Order

CY62168DV30LL-55BVXI CY62168DV30LL-55BVXI IC SRAM 16M PARALLEL 48VFBGA 3528

More on Order

CY62136VLL-70ZSXET CY62136VLL-70ZSXET IC SRAM 2M PARALLEL 44TSOP II 6102

More on Order

CY62127DV30LL-55ZXIT CY62127DV30LL-55ZXIT IC SRAM 1M PARALLEL 44TSOP II 4068

More on Order

CY62128BLL-70ZXI CY62128BLL-70ZXI IC SRAM 1M PARALLEL 32TSOP I 5598

More on Order

CY62167GN18-55BVXIT CY62167GN18-55BVXIT IC SRAM 16M PARALLEL 6714

More on Order

CY62157ELL-55BVXET CY62157ELL-55BVXET IC SRAM 8M PARALLEL 48VFBGA 4320

More on Order

CY62158H-45ZSXIT CY62158H-45ZSXIT IC SRAM 8M PARALLEL 3258

More on Order

CY62147GE30-45ZSXIT CY62147GE30-45ZSXIT MICROPOWER SRAMS 5400

More on Order

CY62146GE30-45ZSXI CY62146GE30-45ZSXI IC SRAM 4M PARALLEL 44TSOP II 6984

More on Order

CY62147G18-55BVXI CY62147G18-55BVXI IC SRAM 4M PARALLEL 48VFBGA 9516

More on Order

CY62148EV30LL-45BVXI CY62148EV30LL-45BVXI IC SRAM 4M PARALLEL 36VFBGA 7656

More on Order

CY62177EV18LL-70BAXI CY62177EV18LL-70BAXI IC SRAM 32M PARALLEL 48FBGA 7716

More on Order

CY62147EV30LL-45BVXI CY62147EV30LL-45BVXI IC SRAM 4M PARALLEL 48VFBGA 835

More on Order

CY62128ELL-45ZXI CY62128ELL-45ZXI IC SRAM 1M PARALLEL 32TSOP I 12544

More on Order