Your search keyword '"Wenjia Yuan"' showing total 8 results

1. What Am I Looking At? Low-Power Radio-Optical Beacons for In-View Recognition on Smart-Glass

Author

Yanyong Zhang, Narayan B. Mandayam, Rich Howard, Ashwin Ashok, Wenjia Yuan, Chenren Xu, Kristin J. Dana, Marco Gruteser, and Tam Vu

Subjects

Computer Networks and Communications, Orientation (computer vision), Computer science, business.industry, Radio Link Protocol, Transmitter, Electrical engineering, Synchronizing, Wearable computer, 020206 networking & telecommunications, 020302 automobile design & engineering, Ranging, 02 engineering and technology, Beacon, law.invention, 0203 mechanical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, business, Software, Energy (signal processing), Simulation

Abstract

Applications on wearable personal imaging devices, or Smart-glasses as they are called, can largely benefit from accurate and energy-efficient recognition of objects that are within the user's view. Existing solutions such as optical or computer vision approaches are too energy intensive, while low-power active radio tags suffer from imprecise orientation estimates. To address this challenge, this paper presents the design, implementation, and evaluation of a radio-optical hybrid system where a radio-optical transmitter, or tag , whose radio-optical beacons are used for accurate relative orientation tracking of tagged objects by a wearable radio-optical receiver. A low-power radio link that conveys identity is used to reduce the battery drain by synchronizing the radio-optical transmitter and receiver so that extremely short optical (infrared) pulses are sufficient for orientation (angle and distance) estimation. Through extensive experiments with our prototype we show that our system can achieve orientation estimates with 1-to-2 degree accuracy and within 40 cm ranging error, with a maximum range of 9 m in typical indoor use cases. With a tag and receiver battery power consumption of 81 $\mu$ W and 90 mW, respectively, our radio-optical tags and receiver are at least 1.5 $\times$ energy efficient than prior works in this space.

Published

2016

2. Capacity of screen–camera communications under perspective distortions

Author

Wenjia Yuan, Narayan B. Mandayam, Marco Gruteser, Ashwin Ashok, Kristin J. Dana, and Shubham Jain

Subjects

Computer Networks and Communications, Computer science, business.industry, Transmitter, Real-time computing, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Short Code, Communications system, Computer Science Applications, Perspective distortion, Hardware and Architecture, Camera auto-calibration, Computer vision, Artificial intelligence, Smart camera, business, computer, Software, Multipath propagation, Information Systems, Communication channel, computer.programming_language

Abstract

Cameras are ubiquitous and increasingly being used not just for capturing images but also for communicating information. For example, the pervasive QR codes can be viewed as communicating a short code to camera-equipped sensors. Such communications could be particularly attractive in pervasive camera based applications, where such camera communications can reuse the existing camera hardware and also leverage from the large pixel array structure for high data-rate communication. While several prototypes have been constructed, the fundamental capacity limits of the screen-camera communication channel in all but the simplest scenarios remains unknown. The visual medium differs from RF in that the information capacity of this channel largely depends on the perspective distortions while multipath becomes negligible. In this paper, we create a model of this communication system to allow predicting the capacity based on receiver perspective (distance and angle to the transmitter). We calibrate and validate this model through lab experiments wherein information is transmitted from a screen and received with a tablet camera. Our capacity estimates indicate that tens of Mbps is possible using a smartphone camera even when the short code on the screen images onto only 15% of the camera frame. Our estimates also indicate that there is room for at least 2.5 i? improvement in throughput of existing screen-camera communication prototypes.

Published

2015

3. Low-Power Radio-Optical Beacons for In-View Recognition

Author

Narayan B. Mandayam, Kristin J. Dana, Wenjia Yuan, Chenren Xu, Ashwin Ashok, Marco Gruteser, Tam Vu, Yanyong Zhang, and Richard Howard

Subjects

Engineering, Radio receiver design, Hardware_GENERAL, business.industry, Transmitter, Electrical engineering, Frequency offset, Software-defined radio, Types of radio emissions, Transmitter power output, business, Remote radio head, Electric beacon

Abstract

Object recognition on wearable devices using computer vision is too energy intensive and challenging when objects are similar looking, while low-power active radio frequency identification (RFID) systems suffer from imprecise orientation (angle and distance) estimates. To address this challenge, this paper presents a novel radio-optical based recognition system where a radio-optical transmitter, or tag, that emits a beacon whose infra-red (IR) signal strength is used for accurate relative orientation tracking of tagged objects at a wearable radio-optical receiver. A low-power radio link that conveys identity is used to reduce the battery drain by synchronizing the radio- optical transmitter and receiver so that extremely short optical pulses are sufficient for precise orientation estimation. Through extensive experiments with our prototype we show that our system can achieve orientation estimates with 1-2 degree accuracy and within 40cm ranging error, with a maximum range of 9m in typical indoor use cases. With a tag battery power consumption of 86µW, the radio-optical tags show potential to achieve about half a decade lifetimes.

Published

2015

4. Phase messaging method for time-of-flight cameras

Author

Kristin J. Dana, Wenjia Yuan, Marco Gruteser, Narayan B. Mandayam, Richard Howard, Ramesh Raskar, Ashwin Ashok, Massachusetts Institute of Technology. Media Laboratory, Program in Media Arts and Sciences (Massachusetts Institute of Technology), and Raskar, Ramesh

Subjects

business.industry, Computer science, Transmitter, Phase (waves), Optical communication, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Communications system, Signal, law.invention, Optics, law, Optical wireless, business, Frequency modulation, Computer hardware, Light-emitting diode

Abstract

Ubiquitous light emitting devices and low-cost commercial digital cameras facilitate optical wireless communication system such as visual MIMO where handheld cameras communicate with electronic displays. While intensity-based optical communications are more prevalent in camera-display messaging, we present a novel method that uses modulated light phase for messaging and time-of-flight (ToF) cameras for receivers. With intensity-based methods, light signals can be degraded by reflections and ambient illumination. By comparison, communication using ToF cameras is more robust against challenging lighting conditions. Additionally, the concept of phase messaging can be combined with intensity messaging for a significant data rate advantage. In this work, we design and construct a phase messaging array (PMA), which is the first of its kind, to communicate to a ToF depth camera by manipulating the phase of the depth camera's infrared light signal. The array enables message variation spatially using a plane of infrared light emitting diodes and temporally by varying the induced phase shift. In this manner, the phase messaging array acts as the transmitter by electronically controlling the light signal phase. The ToF camera acts as the receiver by observing and recording a time-varying depth. We show a complete implementation of a 3×3 prototype array with custom hardware and demonstrating average bit accuracy as high as 97.8%. The prototype data rate with this approach is 1 Kbps that can be extended to approximately 10 Mbps., National Science Foundation (U.S.) (grant CNS-106546#)

Published

2014

5. Capacity of pervasive camera based communication under perspective distortions

Author

Kristin J. Dana, Ashwin Ashok, Shubham Jain, Wenjia Yuan, Narayan B. Mandayam, and Marco Gruteser

Subjects

Computer science, business.industry, Transmitter, Real-time computing, Frame (networking), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Short Code, Throughput, Communications system, Computer vision, Artificial intelligence, Smart camera, business, computer, Multipath propagation, computer.programming_language, Communication channel

Abstract

Cameras are ubiquitous and increasingly being used not just for capturing images but also for communicating information. For example, the pervasive QR codes can be viewed as communicating a short code to camera-equipped sensors and recent research has explored using screen-to-camera communications for larger data transfers. Such communications could be particularly attractive in pervasive camera based applications, where such camera communications can reuse the existing camera hardware and also leverage from the large pixel array structure for high data-rate communication. While several prototypes have been constructed, the fundamental capacity limits of this novel communication channel in all but the simplest scenarios remains unknown. The visual medium differs from RF in that the information capacity of this channel largely depends on the perspective distortions while multipath becomes negligible. In this paper, we create a model of this communication system to allow predicting the capacity based on receiver perspective (distance and angle to the transmitter). We calibrate and validate this model through lab experiments wherein information is transmitted from a screen and received with a tablet camera. Our capacity estimates indicate that tens of Mbps is possible using a smartphone camera even when the short code on the screen images onto only 15% of the camera frame. Our estimates also indicate that there is room for at least 2.5x improvement in throughput of existing screen - camera communication prototypes.

Published

2014

6. Dynamic and invisible messaging for visual MIMO

Author

Wenjia Yuan, Kristin J. Dana, Ashwin Ashok, Narayan B. Mandayam, and Marco Gruteser

Subjects

Pixel, business.industry, Computer science, MIMO, Feature extraction, Transmitter, Visualization, Wireless, Computer vision, Artificial intelligence, business, Image retrieval, Computer hardware, Communication channel

Abstract

The growing ubiquity of cameras in hand-held devices and the prevalence of electronic displays in signage creates a novel framework for wireless communications. Traditionally, the term MIMO is used for multiple-input multiple-output where the multiple-input component is a set of radio transmitters and the multiple-output component is a set of radio receivers. We employ the concept of visual MIMO where pixels are transmitters and cameras are receivers. In this manner, the techniques of computer vision can be combined with principles from wireless communications to create an optical line-of-sight communications channel. Two major challenges are addressed: (1) The message for transmission must be embedded in the observed display so that the message is hidden from the observer and the electronic display can simultaneously be used for its originally intended purpose (e.g. signage, advertisements, maps); (2) Photometric and geometric distortions during the imaging process corrupt the information channel between the transmitter display and the receiver camera. These distortions must be modeled and removed. In this paper, we present a real-time messaging paradigm and its implementation in an operational visual MIMO optical systems. As part of the system, we develop a novel algorithm for photographic message extraction which includes automatic display detection, message embedding and message retrieval. Experiments show that the system achieves an average accuracy of 94.6% at the bitrate of 6222.2 bps.

Published

2012

7. Demo

Author

Marco Gruteser, Michael Varga, Wenjia Yuan, Narayan B. Mandayam, Kristin J. Dana, and Ashwin Ashok

Subjects

3G MIMO, business.industry, Computer science, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, Transmitter, MIMO, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Automobile safety, Communications system, Multi-user MIMO, Proof of concept, Embedded system, Optical wireless, business, Computer hardware

Abstract

The inherent limitations in RF spectrum availability and susceptibility to interference make it difficult to meet the reliability required for automotive safety applications. To address this challenge, this work explores an alternative communication system called Visual MIMO that uses light emitting arrays as transmitters and cameras as receivers. Visual MIMO applied to vehicular communication proposes to reuse existing LED rear and headlights as transmitters and existing cameras (e.g. those used for parking assistance, rear-view cameras) as receivers. In this work we show a proof of concept based demonstration of the Visual MIMO system consisting of an LED transmitter array and a high-speed camera.

Published

2011

8. Computer vision methods for visual MIMO optical system

Author

Kristin J. Dana, Marco Gruteser, Wenjia Yuan, Ashwin Ashok, Michael Varga, and Narayan B. Mandayam

Subjects

business.industry, Computer science, Transmitter, MIMO, Optical communication, Communications system, Multi-user MIMO, Embedded system, Optical wireless, Artificial intelligence, Image sensor, business, Mobile device, Computer hardware, Communication channel

Abstract

Cameras have become commonplace in phones, laptops, music-players and handheld games. Similarly, light emitting displays are prevalent in the form of electronic billboards, televisions, computer monitors, and hand-held devices. The prevalence of cameras and displays in our society creates a novel opportunity to build camera-based optical wireless communication systems based on a concept called visual MIMO. We extend the common term MIMO from the field of communications (“multiple-input multiple-output”) that is typically used to describe multiple antenna, multiple transmitter radio frequency communications channel. In the visual MIMO communications paradigm, the transmitters are light-emitting devices such as electronic displays and cameras are the receivers. In this paper we discuss and address several challenges in creating a visual MIMO channel. These challenges include: (1) electronic display detection, (2) embedding the transmission signal in the display video, and (3) system characterization for electronic display appearance.

Published

2011