Light sources Photonics commonly uses semiconductor-based light sources, such as
light-emitting diodes (LEDs),
superluminescent diodes, and lasers. Other light sources include
single photon sources,
fluorescent lamps,
cathode-ray tubes (CRTs), and
plasma screens. Note that while CRTs, plasma screens, and
organic light-emitting diode displays generate their own light,
liquid crystal displays (LCDs) like
TFT screens require a
backlight of either
cold cathode fluorescent lamps or, more often today, LEDs. Characteristic for research on semiconductor light sources is the frequent use of
III-V semiconductors instead of the classical semiconductors like
silicon and
germanium. This is due to the special properties of
III-V semiconductors that allow for the implementation of
light emitting devices. Examples for material systems used are
gallium arsenide (GaAs) and
aluminium gallium arsenide (AlGaAs) or other
compound semiconductors. They are also used in conjunction with silicon to produce
hybrid silicon lasers.
Transmission media Light can be transmitted through any
transparent medium.
Glass fiber or
plastic optical fiber can be used to guide the light along a desired path. In
optical communications optical fibers allow for
transmission distances of more than 100 km without amplification depending on the bit rate and modulation format used for transmission. A very advanced research topic within photonics is the investigation and fabrication of special structures and "materials" with engineered optical properties. These include
photonic crystals,
photonic crystal fibers and
metamaterials.
Amplifiers Optical amplifiers are used to amplify an optical signal. Optical amplifiers used in optical communications are
erbium-doped fiber amplifiers,
semiconductor optical amplifiers,
Raman amplifiers and
optical parametric amplifiers. A very advanced research topic on optical amplifiers is the research on
quantum dot semiconductor optical amplifiers.
Detection Photodetectors detect light. Photodetectors range from very fast
photodiodes for communications applications over medium speed charge coupled devices (
CCDs) for
digital cameras to very slow
solar cells that are used for
energy harvesting from
sunlight. There are also many other photodetectors based on thermal,
chemical, quantum,
photoelectric and other effects.
Modulation Modulation of a light source is used to encode information on a light source. Modulation can be achieved by the light source directly. One of the simplest examples is to use a
flashlight to send
Morse code. Another method is to take the light from a light source and modulate it in an external
optical modulator. An additional topic covered by modulation research is the modulation format.
On-off keying has been the commonly used modulation format in optical communications. In the last years more advanced modulation formats like
phase-shift keying or even
orthogonal frequency-division multiplexing have been investigated to counteract effects like
dispersion that degrade the quality of the transmitted signal.
Photonic systems Photonics also includes research on photonic systems. This term is often used for
optical communication systems. This area of research focuses on the implementation of photonic systems like high speed photonic networks. This also includes research on
Optical communications repeaters, which improve optical signal quality.
Photonic integrated circuits Photonic integrated circuits (PICs) are optically active integrated semiconductor photonic devices. The leading commercial application of PICs are optical transceivers for data center optical networks. PICs fabricated on III-V
indium phosphide semiconductor wafer substrates were the first to achieve commercial success; PICs based on silicon wafer substrates are now also a commercialized technology. Key Applications for Integrated Photonics include: • Data Center Interconnects: Data centers continue to grow in scale as companies and institutions store and process more information in the cloud. With the increase in data center compute, the demands on data center networks correspondingly increase. Optical cables can support greater lane bandwidth at longer transmission distances than copper cables. For short-reach distances and up to 40 Gbit/s data transmission rates, non-integrated approaches such as
vertical-cavity surface-emitting lasers can be used for optical transceivers on
multi-mode optical fiber networks. Beyond this range and bandwidth, photonic integrated circuits are key to enable high-performance, low-cost optical transceivers. • Analog RF Signal Applications: Using the GHz precision signal processing of photonic integrated circuits, radiofrequency (RF) signals can be manipulated with high fidelity to add or drop multiple channels of radio, spread across an ultra-broadband frequency range. In addition, photonic integrated circuits can remove background noise from an RF signal with unprecedented precision, which will increase the signal to noise performance and make possible new benchmarks in low power performance. Taken together, this high precision processing enables us to now pack large amounts of information into ultra-long-distance radio communications. • Sensors: Photons can also be used to detect and differentiate the optical properties of materials. They can identify chemical or biochemical gases from air pollution, organic produce, and contaminants in the water. They can also be used to detect abnormalities in the blood, such as low glucose levels, and measure biometrics such as pulse rate. •
LIDAR and other
phased array imaging: Arrays of PICs can take advantage of phase delays in the light reflected from objects with three-dimensional shapes to reconstruct 3D images, and Light Imaging, Detection and Ranging (LIDAR) with laser light can offer a complement to
radar by providing precision imaging (with 3D information) at close distances. This new form of
machine vision is having an immediate application in driverless cars to reduce collisions, and in biomedical imaging. Phased arrays can also be used for free-space communications and novel display technologies. Current versions of LIDAR predominantly rely on moving parts, making them large, slow, low resolution, costly, and prone to mechanical vibration and premature failure. Integrated photonics can realize LIDAR within a footprint the size of a postage stamp, scan without moving parts, and be produced in high volume at low cost.
Biophotonics Biophotonics employs tools from the field of photonics to the study of
biology. Biophotonics mainly focuses on improving medical diagnostic abilities (for example for cancer or infectious diseases) but can also be used for environmental or other applications. The main advantages of this approach are speed of analysis,
non-invasive diagnostics, and the ability to work
in-situ. ==See also==