LEADER 04605nam  22008893a 450 
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005 20250203235431.0
010   $a9783039214365
010   $a3039214365
024 8 $a10.3390/books978-3-03921-436-5
035   $a(CKB)4100000010106235
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/62263
035   $a(ScCtBLL)756a3c15-306d-43de-a7cb-57ac3691829b
035   $a(OCoLC)1163816571
035   $a(oapen)doab62263
035   $a(EXLCZ)994100000010106235
100   $a20250203i20192019  uu 
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aVisible Light Communication and Positioning$fChen Gong
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
210  1$aBasel, Switzerland :$cMDPI,$d2019.
215   $a1 electronic resource (144 p.)
311 08$a9783039214358 
311 08$a3039214357 
330   $aIn recent years, wireless communications have significantly evolved due to the advanced technology of smartphones;, portable devices; and the rapid growth of Internet of Things, e-Health, and intelligent transportation systems . Moreover, there is anare increasing need fors of emerging intelligent services like positioning and sensing in athe future intelligence society. Recent years have witnessed the growing research interests and activities in the communication and intelligencet services in the optical wireless spectrum, as a complementary technology to more  established radio frequency (RF)-based systems, to overcome the spectrum sparsity  and increases data rates in crowded locations, due to the limited transmission range and interference. The OWC technology offers advantages such as free license, wide bandwidth, inherent security, no RF electromagnetic interference, and immunity to electromagnetic interference. The attractive applications of the optical spectrum include ultra-violet tactic communication, blue/green underwater communication, visible light positioning, and vehicular communication/sensing in intelligent transportation systems. The present Iissue, as named "Visible Light Communication and Positioning", focuses on visible light communication and visible light positioning, where four papers are on visible light communication and three papers are on visible light positioning. For visible light communication, the published works focus on the devices, the physical-layer techniques, and the system work aspects. Besides VLC, visible light positioning works include fingerprint-based indoor positioning system for multiple reflections, the impact of LED tilt on visible light positioning accuracy, and a mobile optoelectronic tracking system based on feedforward control.
610   $asofware defined optics (SDO)
610   $alight to frequency converter
610   $awhite-light LED
610   $aerror observer
610   $anature conditions (thermal turbulence
610   $acolor independence
610   $afeedforward control
610   $avisible light communication
610   $aadaptive power allocation scheme
610   $arandom forest (RF)
610   $alocalization algorithm
610   $ageneralized color modulation
610   $awearable device
610   $apositioning
610   $atracking performance
610   $asoftware defined radio (SDR)
610   $aVLP
610   $amultistate quadrature amplitude modulation (M-QAM)
610   $afog)
610   $arain
610   $avisible light communication (VLC)
610   $aLED tail-light
610   $aoptical wireless communication
610   $aLED indoor ceiling light
610   $amultipath reflections
610   $ak-nearest neighbors (kNN)
610   $abit-error ratio (BER)
610   $aanti-disturbance ability
610   $avehicle-to-everything (V2X)
610   $amobile optoelectronic tracking system
610   $adisturbance observer
610   $amodel reference
610   $aindoor positioning system (IPS)
610   $afitting model
610   $aVisible Light Positioning
610   $aLED tilt
610   $ainverse power allocation scheme
610   $anon-orthogonal multiple access
610   $aV2X
610   $avisual MIMO
610   $acolor-space-based modulation
700   $aGong$b Chen$01333805
801  0$bScCtBLL
801  1$bScCtBLL
906   $aBOOK
912   $a9910670796303321
996   $aVisible Light Communication and Positioning$93043876
997   $aUNINA