Shintaro Arai scite author profile

As a new technology for next-generation vehicle-to-everything (V2X) communication, visible-light communication (VLC) using light-emitting diode (LED) transmitters and camera receivers has been energetically studied. Toward the future in which vehicles are connected anytime and anywhere by optical signals, the cutting-edge camera receiver employing a special CMOS image sensor, i.e., the optical communication image sensor (OCI), has been prototyped, and an optical V2V communication system applying this OCI-based camera receiver has already demonstrated 10-Mb/s optical signal transmission between real vehicles during outside driving. In this paper, to reach a transmission performance of 54 Mb/s, which is standardized as the maximum data rate in IEEE 802.11p for V2X communication, a more advanced OCI-based automotive VLC system is described. By introducing optical orthogonal frequency-division multiplexing (optical-OFDM), the new system achieves a more than fivefold higher data rate. Additionally, the frequency response characteristics and circuit noise of the OCI are closely analyzed and taken into account in the signal design. Furthermore, the forward-current limitation of an actual LED is also considered for long operational reliability, i.e., the LED is not operated in overdrive. Bit-error-rate experiments verify a system performance of 45 Mb/s without bit errors and 55 Mb/s with BER G 10 À5 .Index Terms: Visible light communication (VLC), intelligent transport system (ITS), vehicleto-vehicle (V2V) communication, infrastructure-to-vehicle (I2V) communication, light-emitting diode (LED), image sensor-based VLC, optical communication image sensor (OCI), optical orthogonal frequency division multiplexing (optical-OFDM).

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Vehicle Motion and Pixel Illumination Modeling for Image Sensor Based Visible Light Communication

Yamazato

Kinoshita

Arai

et al. 2015

IEEE J. Select. Areas Commun.

118

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Experimental on Hierarchical Transmission Scheme for Visible Light Communication using LED Traffic Light and High-Speed Camera

Arai

Mase

Yamazato

et al. 2007

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Removal Characteristics of Immunoglobulin G Subclasses by Conventional Plasma Exchange and Selective Plasma Exchange

et al. 2015

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Selective plasma exchange (SePE) using a selective membrane separator is a modified method of simple plasma exchange (PE). Immunoglobulin G (IgG) subclass distribution is one of the important immunological characteristics of IgG. However, there is little information regarding the removal characteristics of IgG subclasses by SePE and conventional PE. Here, we investigated the removal ratio of IgG subclasses by PE and SePE in seven patients with immunological disorders. When the mean processed volume was 0.88 plasma volume (PV) (corresponding to 2.12 L), the mean percent reductions by PE were as follows: IgG, 63.2%; IgG1, 64.5%; IgG2, 64.0%; IgG3, 61.4%; and IgG4, 69.5%. When the mean processed volume was 1.18 PV (corresponding to 2.98 L), the mean percent reductions by SePE were as follows: IgG, 51.6%; IgG1, 55.3%; IgG2, 52.0%; IgG3, 53.7%; and IgG4, 64.6%. In both PE and SePE, using albumin solution as the supplementary fluid, IgG was effectively eliminated regardless of IgG subclasses.

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Shintaro Arai

Image-sensor-based visible light communication for automotive applications

A New Automotive VLC System Using Optical Communication Image Sensor

Vehicle Motion and Pixel Illumination Modeling for Image Sensor Based Visible Light Communication

Experimental on Hierarchical Transmission Scheme for Visible Light Communication using LED Traffic Light and High-Speed Camera

Removal Characteristics of Immunoglobulin G Subclasses by Conventional Plasma Exchange and Selective Plasma Exchange

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