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Visible light communication

January 01, 1970

In telecommunications, visible light communication (VLC) is the use of visible light (light with a frequency of 400–800 THz/wavelength of 780–375 nm) as a transmission medium. VLC is a subset of optical wireless communications technologies.

Visible light is only a small portion of the electromagnetic spectrum.

The technology uses fluorescent lamps (ordinary lamps, not special communications devices) to transmit signals at 10 kbit/s, or LEDs for up to 500 Mbit/s over short distances. Systems such as RONJA can transmit at full Ethernet speed (10 Mbit/s) over distances of 1–2 kilometres (0.6–1.2 mi).

Specially designed electronic devices generally containing a photodiode receive signals from light sources,[1] although in some cases a cell phone camera or a digital camera will be sufficient.[2] The image sensor used in these devices is in fact an array of photodiodes (pixels) and in some applications its use may be preferred over a single photodiode. Such a sensor may provide either multi-channel (down to 1 pixel = 1 channel) or a spatial awareness of multiple light sources.[1]

VLC can be used as a communications medium for ubiquitous computing, because light-producing devices (such as indoor/outdoor lamps, TVs, traffic signs, commercial displays and car headlights/taillights[3]) are used everywhere.[2]

Uses edit

One of the main characteristics of VLC is the incapacity of light to surpass physical opaque barriers. This characteristic can be considered a weak point of VLC, due to the susceptibility of interference from physical objects, but is also one of its many strengths: unlike radio waves, light waves are confined in the enclosed spaces they are transmitted, which enforces a physical safety barrier that requires a receptor of that signal to have physical access to the place where the transmission is occurring.[4]

A promising application of VLC is the Indoor Positioning System (IPS), an analogue to GPS which is built to operate in enclosed spaces where GPS satellite transmissions cannot reach. For instance, commercial buildings, shopping malls, parking garages, as well as subways and tunnel systems are all possible applications for VLC-based indoor positioning systems. Additionally, once the VLC lamps are able to perform lighting at the same time as data transmission, it can simply occupy the installation of traditional single-function lamps.

Other applications for VLC involve communication between appliances of a smart home or office. With increasing IoT-capable devices, connectivity through traditional radio waves might be subjected to interference.[5] Light bulbs with VLC capabilities can transmit data and commands for such devices.

History edit

The history of visible light communications dates back to the 1880s in Washington, D.C., when the Scottish-born scientist Alexander Graham Bell invented the photophone, which transmitted speech on modulated sunlight over several hundred meters. This pre-dates the transmission of speech by radio.

More recent work began in 2003 at Nakagawa Laboratory, in Keio University, Japan, using LEDs to transmit data by visible light. Since then there have been numerous research activities focussed on VLC.

In 2006, researchers from CICTR at Penn State proposed a combination of power line communication (PLC) and white light LED to provide broadband access for indoor applications.[6] This research suggested that VLC could be deployed as a perfect last-mile solution in the future.

In January 2010 a team of researchers from Siemens and Fraunhofer Institute for Telecommunications, Heinrich Hertz Institute, in Berlin, demonstrated transmission at 500 Mbit/s with a white LED over a distance of 5 metres (16 ft), and 100 Mbit/s over longer distance using five LEDs.[7]

The VLC standardization process is conducted within the IEEE 802.15.7 working group.

In December 2010 St. Cloud, Minnesota, signed a contract with LVX Minnesota and became the first to commercially deploy this technology.[8]

In July 2011 a presentation at TED Global[9] gave a live demonstration of high-definition video being transmitted from a standard LED lamp, and proposed the term Li-Fi to refer to a subset of VLC technology.

Recently, VLC-based indoor positioning systems have become an attractive topic. ABI research forecasts that it could be a key solution to unlocking the $5 billion "indoor location market".[10] Publications have been coming from Nakagawa Laboratory,[11] ByteLight filed a patent[12] on a light positioning system using LED digital pulse recognition in March 2012.[13][14] COWA at Penn State[15][16] and other researchers around the world.[17][18]

Another recent application is in the world of toys, thanks to cost-efficient and low-complexity implementation, which only requires one microcontroller and one LED as optical front-end.[19]

VLCs can be used for providing security.[20][21] They are especially useful in body sensor networks and personal area networks.

Recently Organic LEDs (OLED) have been used as optical transceivers to build up VLC communication links up to 10 Mbit/s.[22]

In October 2014, Axrtek launched a commercial bidirectional RGB LED VLC system called MOMO that transmits down and up at speeds of 300 Mbit/s and with a range of 25 feet.[23]

In May 2015, Philips collaborated with supermarket company Carrefour to deliver VLC location-based services to shoppers' smartphones in a hypermarket in Lille, France.[24] In June 2015, two Chinese companies, Kuang-Chi and Ping An Bank, partnered to introduce a payment card that communicates information through a unique visible light.[25] In March 2017, Philips set up the first VLC location-based services to shoppers' smartphones in Germany. The installation was presented at EuroShop in Düsseldorf (5–9 March). As first supermarket in Germany an Edeka supermarket in Düsseldorf-Bilk is using the system, which offers a 30 centimeter positioning accuracy can be achieved, which meets the special demands in food retail.[26][27] Indoor positioning systems based on VLC[28] can be used in places such as hospitals, eldercare homes, warehouses, and large, open offices to locate people and control indoor robotic vehicles.

There is wireless network that for data transmission uses visible light, and does not use intensity modulation of optical sources. The idea is to use vibration generator instead of optical sources for data transmission.[29]

Modulation Techniques edit

In order to send data, a modulation of light is required. A modulation is the form in which the light signal varies in order to represent different symbols. In order for the data to be decoded. Unlike radio transmission, a VLC modulation requires the light signal to be modulated around a positive dc value, responsible for the lighting aspect of the lamp. The modulation will thus be an alternating signal around the positive dc level, with a high-enough frequency to be imperceptible to the human eye.[30]

Due to this superposition of signals, implementation of VLC transmitter usually require a high-efficiency, higher-power, slower response DC converter responsible for the LED bias that will provide lighting, alongside a lower-efficiency, lower-power, but higher response velocity amplifier in order to synthesize the required AC current modulation.

There are several modulation techniques available, forming three main groups:[31] Single-Carrier Modulated Transmission (SCMT), Multi-Carrier Modulated Transmission (MCMT) and Pulse-Based Transmission (PBT).

Single-Carrier Modulated Transmission edit

The Single-Carrier Modulated Transmission comprises modulation techniques established for traditional forms of transmission, such as radio. A sinusoidal wave is added to the lighting dc level, allowing digital information to be coded in the characteristics of the wave. By keying between two or several different values of a given characteristic, symbols attributed to each value are transmitted on the light link.

Possible techniques are Amplitude Switch Keying (ASK), Phase Switch Keying (PSK) and Frequency Switch Keying (FSK). Out of these three, FSK is capable of larger bitrate transmission once it allows more symbols to be easily differentiated on frequency switching. An additional technique called Quadrature Amplitude Modulation (QAM) has also been proposed, where both amplitude and phase of the sinusoidal voltage are keyed simultaneously in order to increase the possible number of symbols.[30]

Multi-Carrier Modulated Transmission edit

Multi-Carrier Modulated Transmission works on the same way of Single-Carrier Modulated Transmission methods, but embed two or more sinusoidal waves modulated for data transmission.[32] This type of modulation is among the hardest and more complex to synthesize and decode. However, it presents the advantage of excelling in multipath transmission, where the receptor is not in direct view of the transmitter and therefore makes the transmission depend on reflection of the light in other barriers.

Pulse-Based Transmission edit

Pulse-Based transmission encompasses modulation techniques in which the data is encoded not on a sinusoidal wave, but on a pulsed wave. Unlike sinusoidal alternating signals, in which the periodic average will always be null, pulsed waves based on high-low states will present inherit average values. This brings two main advantages for the Pulse-Based Transmission modulations:

It can be implemented with a single high-power, high-efficiency, dc converter of slow response and an additional power switch operating in fast speeds to deliver current to the LED at determined instants. Once the average value depends on the pulse width of the data signal, the same switch that operates the data transmission can provide dimming control, greatly simplifying the dc converter.

Due to these important implementation advantages, these dimming-capable modulations have been standardized in IEEE 802.15.7, in which are described three modulation techniques: On-Off Keying (OOK), Variable Pulse Position Modulation (VPPM) and Color Shift Keying (CSK).

On-Off Keying edit

On the On-Off Keying technique, the LED is switched on and off repeatedly, and the symbols are differentiated by the pulse width, with a wider pulse representing the logical high '1', while narrower pulses representing logical low '0'. Because the data is encoded on the pulse width, the information sent will affect the dimming level if not corrected: for instance, a bitstream with several high values '1' will appear brighter than a bitstream with several low values '0'. In order to fix this problem, the modulation requires a compensation pulse that will be inserted on the data period whenever necessary to equalize the brightness overall. The lack of this compensation symbol could introduce perceived flickering, which is undesirable.

Because of the additional compensation pulse, modulating this wave is slightly more complex than modulating the VPPM. However, the information encoded on the pulse width is easy to differentiate and decode, so the complexity of the transmitter is balanced by the simplicity of the receiver.

Variable Pulse Position Modulation edit

Variable Pulse Position also switches the LED on and off repeatedly, but encode the symbols on the pulse position inside the data period. Whenever the pulse is located at the immediate beginning of the data period, the transmitted symbol is standardized as logical low '0', with logical high '1' being composed of pulses that end with the data period. Because the information is encoded at the location of the pulse inside the data period, both pulses can and will have the same width, and thus, no compensation symbol is required. Dimming is performed by the transmitting algorithm, that will select the width of the data pulses accordingly.

The lack of a compensation pulse makes VPPM marginally simpler to encode when compared to OOK. However, a slightly more complex demodulation compensates for that simplicity on the VPPM technique. This decoding complexity mostly comes from the information being encoded at different rising edges for each symbol, which makes the sampling harder in a microcontroller. Additionally, in order to decode the location of a pulse within the data period, the receptor must be somehow synchronized with the transmitter, knowing exactly when a data period starts and how long it lasts. These characteristics makes the demodulation of a VPPM signal slightly more difficult to implement.

Color Shift Keying edit

Color shift keying (CSK), outlined in IEEE 802.15.7, is an intensity modulation based modulation scheme for VLC. CSK is intensity-based, as the modulated signal takes on an instantaneous color equal to the physical sum of three (red/green/blue) LED instantaneous intensities. This modulated signal jumps instantaneously, from symbol to symbol, across different visible colors; hence, CSK can be construed as a form of frequency shifting. However, this instantaneous variation in the transmitted color is not to be humanly perceptible, because of the limited temporal sensitivity in the human vision — the "critical flicker fusion threshold" (CFF) and the "critical color fusion threshold" (CCF), both of which cannot resolve temporal changes shorter than 0.01 second. The LEDs’ transmissions are, therefore, preset to time-average (over the CFF and the CCF) to a specific time-constant color. Humans can thus perceive only this preset color that seems constant over time, but cannot perceive the instantaneous color that varies rapidly in time. In other words, CSK transmission maintains a constant time-averaged luminous flux, even as its symbol sequence varies rapidly in chromaticity.[33]

See also edit

References edit

  1. ^ a b "Image Sensor Communication". VLC Consortium.[dead link]
  2. ^ a b . VLC Consortium. Archived from the original on December 3, 2009.
  3. ^ . VLC Consortium. Archived from the original on January 28, 2010.
  4. ^ Dimitrov, Svilen; Haas, Harald (2015). Principles of LED Light Communications: Towards Networked Li-Fi. Cambridge: Cambridge University Press. doi:10.1017/cbo9781107278929. ISBN 978-1-107-04942-0.
  5. ^ "Cisco Annual Internet Report - Cisco Annual Internet Report (2018–2023) White Paper". Cisco. Retrieved 2020-10-21.
  6. ^ M. Kavehrad, P. Amirshahi, "Hybrid MV-LV Power Lines and White Light Emitting Diodes for Triple-Play Broadband Access Communications," IEC Comprehensive Report on Achieving the Triple Play: Technologies and Business Models for Success, ISBN 1-931695-51-2, pp. 167-178, January 2006. See publication here 2016-03-04 at the Wayback Machine
  7. ^ (Press release). Siemens. January 18, 2010. Archived from the original on September 29, 2012. Retrieved June 21, 2012.
  8. ^ "St. Cloud first to sign on for new technology" (Press release). St. Cloud Times. Nov 19, 2010.
  9. ^ "Wireless data from every light bulb". 2 August 2011.
  10. ^ "LED and Visible Light Communications Could be Key to Unlocking $5 Billion Indoor Location Market". www.abiresearch.com.
  11. ^ Yoshino, M.; Haruyama, S.; Nakagawa, M.; "High-accuracy positioning system using visible LED lights and image sensor," Radio and Wireless Symposium, 2008 IEEE, vol., no., pp.439-442, 22-24 Jan. 2008.
  12. ^ "Light positioning system using digital pulse recognition".
  13. ^ Yoshino, Masaki; Haruyama, Shinichiro; Nakagawa, Masao (1 January 2008). "High-accuracy positioning system using visible LED lights and image sensor". 2008 IEEE Radio and Wireless Symposium. pp. 439–442. doi:10.1109/RWS.2008.4463523. ISBN 978-1-4244-1462-8. S2CID 1023383 – via IEEE Xplore.
  14. ^ S. Horikawa, T. Komine, S. Haruyama and M. Nakagawa,”Pervasive Visible Light Positioning System using White LED Lighting”, IEICE, CAS2003-142, 2003.
  15. ^ Zhang, W.; Kavehrad, M. (2012). "A 2-D indoor localization system based on visible light LED". 2012 IEEE Photonics Society Summer Topical Meeting Series. pp. 80–81. doi:10.1109/PHOSST.2012.6280711. ISBN 978-1-4577-1527-3. S2CID 10835473.
  16. ^ Lee, Yong Up; Kavehrad, Mohsen (2012). "Long-range indoor hybrid localization system design with visible light communications and wireless network". 2012 IEEE Photonics Society Summer Topical Meeting Series. pp. 82–83. doi:10.1109/PHOSST.2012.6280712. ISBN 978-1-4577-1527-3. S2CID 43879184.
  17. ^ Panta, K.; Armstrong, J. (2012). "Indoor localisation using white LEDs". Electronics Letters. 48 (4): 228. Bibcode:2012ElL....48..228P. doi:10.1049/el.2011.3759.
  18. ^ Kim, Hyun-Seung; Kim, Deok-Rae; Yang, Se-Hoon; Son, Yong-Hwan; Han, Sang-Kook (2011). "Indoor positioning system based on carrier allocation visible light communication". 2011 International Quantum Electronics Conference (IQEC) and Conference on Lasers and Electro-Optics (CLEO) Pacific Rim incorporating the Australasian Conference on Optics, Lasers and Spectroscopy and the Australian Conference on Optical Fibre Technology. pp. 787–789. doi:10.1109/IQEC-CLEO.2011.6193741. ISBN 978-0-9775657-8-8. S2CID 23878390.
  19. ^ Giustiniano, Domenico; Tippenhauer, Nils Ole; Mangold, Stefan (2012). "Low-complexity Visible Light Networking with LED-to-LED communication". 2012 IFIP Wireless Days. pp. 1–8. doi:10.1109/WD.2012.6402861. ISBN 978-1-4673-4404-3. S2CID 14931354.
  20. ^ Xin Huang; Bangdao Chen; A.W. Roscoe; "Multi−Channel Key Distribution Protocols Using Visible Light Communications in Body Sensor Networks", Computer Science Student Conference 2012, (pp. 15), Nov. 2012., See publication here
  21. ^ Huang, X.; Guo, S.; Chen, B.; Roscoe, A. W. (2012). Bootstrapping body sensor networks using human controlled LED-camera channels. pp. 433–438. ISBN 978-1-4673-5325-0.
  22. ^ Haigh, Paul Anthony; Bausi, Francesco; Ghassemlooy, Zabih; Papakonstantinou, Ioannis; Le Minh, Hoa; Fléchon, Charlotte; Cacialli, Franco (2014). "Visible light communications: Real time 10 Mb/S link with a low bandwidth polymer light-emitting diode". Optics Express. 22 (3): 2830–8. Bibcode:2014OExpr..22.2830H. doi:10.1364/OE.22.002830. PMID 24663574.
  23. ^ Axrtek MOMO Axrtek, Inc.
  24. ^ "Where are the discounts? Carrefour's LED supermarket lighting from Philips will guide you" (Press release). Philips. May 21, 2015.
  25. ^ Chen, Guojing (June 28, 2015). . China Economic Net. Archived from the original on October 3, 2018.
  26. ^ "Two more indoor positioning projects sprout in European supermarkets". www.ledsmagazine.com. 2017-03-08.
  27. ^ "Favendo collaborates with Philips Lighting" (PDF).
  28. ^ "Visible Light Communication". www.ntu.edu.sg. Retrieved 2015-12-24.
  29. ^ Bodrenko, A.I. (2018). "New Wireless Technology Not Covered by the Existing IEEE Standards of 2017". International Research Journal. 4 (70). doi:10.23670/IRJ.2018.70.022.
  30. ^ a b Rodríguez, Juan; Lamar, Diego G.; Aller, Daniel G.; Miaja, Pablo F.; Sebastián, Javier (April 2018). "Efficient Visible Light Communication Transmitters Based on Switching-Mode dc-dc Converters". Sensors. 18 (4): 1127. Bibcode:2018Senso..18.1127R. doi:10.3390/s18041127. PMC 5948605. PMID 29642455.
  31. ^ Sebastian, Javier; Lamar, Diego G.; Aller, Daniel G.; Rodriguez, Juan; Miaja, Pablo F. (September 2018). "On the Role of Power Electronics in Visible Light Communication". IEEE Journal of Emerging and Selected Topics in Power Electronics. 6 (3): 1210–1223. doi:10.1109/JESTPE.2018.2830878. hdl:10651/46845. ISSN 2168-6777. S2CID 19092607.
  32. ^ Rodreguez, Juan; Lamar, Diego G.; Aller, Daniel G.; Miaja, Pablo F.; Sebastian, Javier (June 2018). "Power-Efficient VLC Transmitter Able to Reproduce Multi-Carrier Modulation Schemes by Using the Output Voltage Ripple of the HB-LED Driver". 2018 IEEE 19th Workshop on Control and Modeling for Power Electronics (COMPEL). Padua: IEEE. pp. 1–8. doi:10.1109/COMPEL.2018.8460175. hdl:10651/48039. ISBN 978-1-5386-5541-2. S2CID 52289901.
  33. ^ Aziz, Amena Ejaz; Wong, Kainam Thomas; Chen, Jung-Chieh (2017). "Color-Shift Keying—How itItsargest Obtainable "Minimum Distance" Depends on its Preset Operating Chromaticity and Constellation Size". Journal of Lightwave Technology. 35 (13): 2724–2733. Bibcode:2017JLwT...35.2724A. doi:10.1109/JLT.2017.2693363. hdl:10397/76267. S2CID 13698944.

Further reading edit

External links edit

  • IEEE 802.15 WPAN Task Group 7 (TG7) Visible Light Communication

January 01, 1970
visible, light, communication, telecommunications, visible, light, communication, visible, light, light, with, frequency, wavelength, transmission, medium, subset, optical, wireless, communications, technologies, visible, light, only, small, portion, electroma. In telecommunications visible light communication VLC is the use of visible light light with a frequency of 400 800 THz wavelength of 780 375 nm as a transmission medium VLC is a subset of optical wireless communications technologies Visible light is only a small portion of the electromagnetic spectrum The technology uses fluorescent lamps ordinary lamps not special communications devices to transmit signals at 10 kbit s or LEDs for up to 500 Mbit s over short distances Systems such as RONJA can transmit at full Ethernet speed 10 Mbit s over distances of 1 2 kilometres 0 6 1 2 mi Specially designed electronic devices generally containing a photodiode receive signals from light sources 1 although in some cases a cell phone camera or a digital camera will be sufficient 2 The image sensor used in these devices is in fact an array of photodiodes pixels and in some applications its use may be preferred over a single photodiode Such a sensor may provide either multi channel down to 1 pixel 1 channel or a spatial awareness of multiple light sources 1 VLC can be used as a communications medium for ubiquitous computing because light producing devices such as indoor outdoor lamps TVs traffic signs commercial displays and car headlights taillights 3 are used everywhere 2 Contents 1 Uses 2 History 3 Modulation Techniques 3 1 Single Carrier Modulated Transmission 3 2 Multi Carrier Modulated Transmission 3 3 Pulse Based Transmission 3 3 1 On Off Keying 3 3 2 Variable Pulse Position Modulation 3 3 3 Color Shift Keying 4 See also 5 References 6 Further reading 7 External linksUses editOne of the main characteristics of VLC is the incapacity of light to surpass physical opaque barriers This characteristic can be considered a weak point of VLC due to the susceptibility of interference from physical objects but is also one of its many strengths unlike radio waves light waves are confined in the enclosed spaces they are transmitted which enforces a physical safety barrier that requires a receptor of that signal to have physical access to the place where the transmission is occurring 4 A promising application of VLC is the Indoor Positioning System IPS an analogue to GPS which is built to operate in enclosed spaces where GPS satellite transmissions cannot reach For instance commercial buildings shopping malls parking garages as well as subways and tunnel systems are all possible applications for VLC based indoor positioning systems Additionally once the VLC lamps are able to perform lighting at the same time as data transmission it can simply occupy the installation of traditional single function lamps Other applications for VLC involve communication between appliances of a smart home or office With increasing IoT capable devices connectivity through traditional radio waves might be subjected to interference 5 Light bulbs with VLC capabilities can transmit data and commands for such devices History editThe history of visible light communications dates back to the 1880s in Washington D C when the Scottish born scientist Alexander Graham Bell invented the photophone which transmitted speech on modulated sunlight over several hundred meters This pre dates the transmission of speech by radio More recent work began in 2003 at Nakagawa Laboratory in Keio University Japan using LEDs to transmit data by visible light Since then there have been numerous research activities focussed on VLC In 2006 researchers from CICTR at Penn State proposed a combination of power line communication PLC and white light LED to provide broadband access for indoor applications 6 This research suggested that VLC could be deployed as a perfect last mile solution in the future In January 2010 a team of researchers from Siemens and Fraunhofer Institute for Telecommunications Heinrich Hertz Institute in Berlin demonstrated transmission at 500 Mbit s with a white LED over a distance of 5 metres 16 ft and 100 Mbit s over longer distance using five LEDs 7 The VLC standardization process is conducted within the IEEE 802 15 7 working group In December 2010 St Cloud Minnesota signed a contract with LVX Minnesota and became the first to commercially deploy this technology 8 In July 2011 a presentation at TED Global 9 gave a live demonstration of high definition video being transmitted from a standard LED lamp and proposed the term Li Fi to refer to a subset of VLC technology Recently VLC based indoor positioning systems have become an attractive topic ABI research forecasts that it could be a key solution to unlocking the 5 billion indoor location market 10 Publications have been coming from Nakagawa Laboratory 11 ByteLight filed a patent 12 on a light positioning system using LED digital pulse recognition in March 2012 13 14 COWA at Penn State 15 16 and other researchers around the world 17 18 Another recent application is in the world of toys thanks to cost efficient and low complexity implementation which only requires one microcontroller and one LED as optical front end 19 VLCs can be used for providing security 20 21 They are especially useful in body sensor networks and personal area networks Recently Organic LEDs OLED have been used as optical transceivers to build up VLC communication links up to 10 Mbit s 22 In October 2014 Axrtek launched a commercial bidirectional RGB LED VLC system called MOMO that transmits down and up at speeds of 300 Mbit s and with a range of 25 feet 23 In May 2015 Philips collaborated with supermarket company Carrefour to deliver VLC location based services to shoppers smartphones in a hypermarket in Lille France 24 In June 2015 two Chinese companies Kuang Chi and Ping An Bank partnered to introduce a payment card that communicates information through a unique visible light 25 In March 2017 Philips set up the first VLC location based services to shoppers smartphones in Germany The installation was presented at EuroShop in Dusseldorf 5 9 March As first supermarket in Germany an Edeka supermarket in Dusseldorf Bilk is using the system which offers a 30 centimeter positioning accuracy can be achieved which meets the special demands in food retail 26 27 Indoor positioning systems based on VLC 28 can be used in places such as hospitals eldercare homes warehouses and large open offices to locate people and control indoor robotic vehicles There is wireless network that for data transmission uses visible light and does not use intensity modulation of optical sources The idea is to use vibration generator instead of optical sources for data transmission 29 Modulation Techniques editIn order to send data a modulation of light is required A modulation is the form in which the light signal varies in order to represent different symbols In order for the data to be decoded Unlike radio transmission a VLC modulation requires the light signal to be modulated around a positive dc value responsible for the lighting aspect of the lamp The modulation will thus be an alternating signal around the positive dc level with a high enough frequency to be imperceptible to the human eye 30 Due to this superposition of signals implementation of VLC transmitter usually require a high efficiency higher power slower response DC converter responsible for the LED bias that will provide lighting alongside a lower efficiency lower power but higher response velocity amplifier in order to synthesize the required AC current modulation There are several modulation techniques available forming three main groups 31 Single Carrier Modulated Transmission SCMT Multi Carrier Modulated Transmission MCMT and Pulse Based Transmission PBT Single Carrier Modulated Transmission edit The Single Carrier Modulated Transmission comprises modulation techniques established for traditional forms of transmission such as radio A sinusoidal wave is added to the lighting dc level allowing digital information to be coded in the characteristics of the wave By keying between two or several different values of a given characteristic symbols attributed to each value are transmitted on the light link Possible techniques are Amplitude Switch Keying ASK Phase Switch Keying PSK and Frequency Switch Keying FSK Out of these three FSK is capable of larger bitrate transmission once it allows more symbols to be easily differentiated on frequency switching An additional technique called Quadrature Amplitude Modulation QAM has also been proposed where both amplitude and phase of the sinusoidal voltage are keyed simultaneously in order to increase the possible number of symbols 30 Multi Carrier Modulated Transmission edit Multi Carrier Modulated Transmission works on the same way of Single Carrier Modulated Transmission methods but embed two or more sinusoidal waves modulated for data transmission 32 This type of modulation is among the hardest and more complex to synthesize and decode However it presents the advantage of excelling in multipath transmission where the receptor is not in direct view of the transmitter and therefore makes the transmission depend on reflection of the light in other barriers Pulse Based Transmission edit Pulse Based transmission encompasses modulation techniques in which the data is encoded not on a sinusoidal wave but on a pulsed wave Unlike sinusoidal alternating signals in which the periodic average will always be null pulsed waves based on high low states will present inherit average values This brings two main advantages for the Pulse Based Transmission modulations It can be implemented with a single high power high efficiency dc converter of slow response and an additional power switch operating in fast speeds to deliver current to the LED at determined instants Once the average value depends on the pulse width of the data signal the same switch that operates the data transmission can provide dimming control greatly simplifying the dc converter Due to these important implementation advantages these dimming capable modulations have been standardized in IEEE 802 15 7 in which are described three modulation techniques On Off Keying OOK Variable Pulse Position Modulation VPPM and Color Shift Keying CSK On Off Keying edit On the On Off Keying technique the LED is switched on and off repeatedly and the symbols are differentiated by the pulse width with a wider pulse representing the logical high 1 while narrower pulses representing logical low 0 Because the data is encoded on the pulse width the information sent will affect the dimming level if not corrected for instance a bitstream with several high values 1 will appear brighter than a bitstream with several low values 0 In order to fix this problem the modulation requires a compensation pulse that will be inserted on the data period whenever necessary to equalize the brightness overall The lack of this compensation symbol could introduce perceived flickering which is undesirable Because of the additional compensation pulse modulating this wave is slightly more complex than modulating the VPPM However the information encoded on the pulse width is easy to differentiate and decode so the complexity of the transmitter is balanced by the simplicity of the receiver Variable Pulse Position Modulation edit Variable Pulse Position also switches the LED on and off repeatedly but encode the symbols on the pulse position inside the data period Whenever the pulse is located at the immediate beginning of the data period the transmitted symbol is standardized as logical low 0 with logical high 1 being composed of pulses that end with the data period Because the information is encoded at the location of the pulse inside the data period both pulses can and will have the same width and thus no compensation symbol is required Dimming is performed by the transmitting algorithm that will select the width of the data pulses accordingly The lack of a compensation pulse makes VPPM marginally simpler to encode when compared to OOK However a slightly more complex demodulation compensates for that simplicity on the VPPM technique This decoding complexity mostly comes from the information being encoded at different rising edges for each symbol which makes the sampling harder in a microcontroller Additionally in order to decode the location of a pulse within the data period the receptor must be somehow synchronized with the transmitter knowing exactly when a data period starts and how long it lasts These characteristics makes the demodulation of a VPPM signal slightly more difficult to implement Color Shift Keying edit Color shift keying CSK outlined in IEEE 802 15 7 is an intensity modulation based modulation scheme for VLC CSK is intensity based as the modulated signal takes on an instantaneous color equal to the physical sum of three red green blue LED instantaneous intensities This modulated signal jumps instantaneously from symbol to symbol across different visible colors hence CSK can be construed as a form of frequency shifting However this instantaneous variation in the transmitted color is not to be humanly perceptible because of the limited temporal sensitivity in the human vision the critical flicker fusion threshold CFF and the critical color fusion threshold CCF both of which cannot resolve temporal changes shorter than 0 01 second The LEDs transmissions are therefore preset to time average over the CFF and the CCF to a specific time constant color Humans can thus perceive only this preset color that seems constant over time but cannot perceive the instantaneous color that varies rapidly in time In other words CSK transmission maintains a constant time averaged luminous flux even as its symbol sequence varies rapidly in chromaticity 33 See also editElectric beacon Fiber optic communication Free space optics Free space optical communication IrDA Same principle as VLC but uses infrared light instead of visible light Li Fi Optical wireless communications RONJAReferences edit a b Image Sensor Communication VLC Consortium dead link a b About Visible Light Communication VLC Consortium Archived from the original on December 3 2009 Intelligent Transport System Visible Light Communication VLC Consortium Archived from the original on January 28 2010 Dimitrov Svilen Haas Harald 2015 Principles of LED Light Communications Towards Networked Li Fi Cambridge Cambridge University Press doi 10 1017 cbo9781107278929 ISBN 978 1 107 04942 0 Cisco Annual Internet Report Cisco Annual Internet Report 2018 2023 White Paper Cisco Retrieved 2020 10 21 M Kavehrad P Amirshahi Hybrid MV LV Power Lines and White Light Emitting Diodes for Triple Play Broadband Access Communications IEC Comprehensive Report on Achieving the Triple Play Technologies and Business Models for Success ISBN 1 931695 51 2 pp 167 178 January 2006 See publication here Archived 2016 03 04 at the Wayback Machine 500 Megabits Second with White LED Light Press release Siemens January 18 2010 Archived from the original on September 29 2012 Retrieved June 21 2012 St Cloud first to sign on for new technology Press release St Cloud Times Nov 19 2010 Wireless data from every light bulb 2 August 2011 LED and Visible Light Communications Could be Key to Unlocking 5 Billion Indoor Location Market www abiresearch com Yoshino M Haruyama S Nakagawa M High accuracy positioning system using visible LED lights and image sensor Radio and Wireless Symposium 2008 IEEE vol no pp 439 442 22 24 Jan 2008 Light positioning system using digital pulse recognition Yoshino Masaki Haruyama Shinichiro Nakagawa Masao 1 January 2008 High accuracy positioning system using visible LED lights and image sensor 2008 IEEE Radio and Wireless Symposium pp 439 442 doi 10 1109 RWS 2008 4463523 ISBN 978 1 4244 1462 8 S2CID 1023383 via IEEE Xplore S Horikawa T Komine S Haruyama and M Nakagawa Pervasive Visible Light Positioning System using White LED Lighting IEICE CAS2003 142 2003 Zhang W Kavehrad M 2012 A 2 D indoor localization system based on visible light LED 2012 IEEE Photonics Society Summer Topical 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from Philips will guide you Press release Philips May 21 2015 Chen Guojing June 28 2015 Commercial banks eye mobile payment innovations China Economic Net Archived from the original on October 3 2018 Two more indoor positioning projects sprout in European supermarkets www ledsmagazine com 2017 03 08 Favendo collaborates with Philips Lighting PDF Visible Light Communication www ntu edu sg Retrieved 2015 12 24 Bodrenko A I 2018 New Wireless Technology Not Covered by the Existing IEEE Standards of 2017 International Research Journal 4 70 doi 10 23670 IRJ 2018 70 022 a b Rodriguez Juan Lamar Diego G Aller Daniel G Miaja Pablo F Sebastian Javier April 2018 Efficient Visible Light Communication Transmitters Based on Switching Mode dc dc Converters Sensors 18 4 1127 Bibcode 2018Senso 18 1127R doi 10 3390 s18041127 PMC 5948605 PMID 29642455 Sebastian Javier Lamar Diego G Aller Daniel G Rodriguez Juan Miaja Pablo F September 2018 On the Role of Power Electronics in Visible Light Communication IEEE Journal of Emerging and Selected Topics in Power Electronics 6 3 1210 1223 doi 10 1109 JESTPE 2018 2830878 hdl 10651 46845 ISSN 2168 6777 S2CID 19092607 Rodreguez Juan Lamar Diego G Aller Daniel G Miaja Pablo F Sebastian Javier June 2018 Power Efficient VLC Transmitter Able to Reproduce Multi Carrier Modulation Schemes by Using the Output Voltage Ripple of the HB LED Driver 2018 IEEE 19th Workshop on Control and Modeling for Power Electronics COMPEL Padua IEEE pp 1 8 doi 10 1109 COMPEL 2018 8460175 hdl 10651 48039 ISBN 978 1 5386 5541 2 S2CID 52289901 Aziz Amena Ejaz Wong Kainam Thomas Chen Jung Chieh 2017 Color Shift Keying How itItsargest Obtainable Minimum Distance Depends on its Preset Operating Chromaticity and Constellation Size Journal of Lightwave Technology 35 13 2724 2733 Bibcode 2017JLwT 35 2724A doi 10 1109 JLT 2017 2693363 hdl 10397 76267 S2CID 13698944 Further reading editDavid G Aviv 2006 Laser Space Communications ARTECH HOUSE ISBN 1 59693 028 4 External links editIEEE 802 15 WPAN Task Group 7 TG7 Visible Light Communication Retrieved from https en wikipedia org w index php title Visible light communication amp oldid 1220793634 Color Shift Keying, wikipedia, wiki, book, books, library,

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