Ripple II: Faster Communication through Physical Vibration
We envision physical vibration as a new modality of
data communication. In NSDI 2015, our paper reported
the feasibility of modulating the vibration of a smartphone’s
vibra-motor. When in physical contact with another
smartphone, the accelerometer of the second phone
was able to decode the vibrations at around 200 bits/s.
This paper builds on our first prototype, but redesigns
the entire radio stack to now achieve 30 kbps. The core
redesign includes (1) a new OFDM-based physical layer
that uses the microphone as a receiver (instead of the accelerometer),
and (2) a MAC layer that detects collision
at the transmitter and performs proactive symbol retransmissions.
We also develop two example applications on
top of the vibratory radio: (1) a finger ring that transmits
vibratory passwords through the finger bone to enable
touch based authentication, and (2) surface communication
between devices placed on the same table. The
overall system entails unique challenges and opportunities,
including ambient sound cancellation, OFDM over
vibrations, back-EMF based carrier sensing, predictive
retransmissions, bone conduction, etc. We call our system
Ripple II to suggest the continuity from the NSDI
2015 paper. We close the paper with a video demo that
streams music as OFDM packets through vibrations and
plays it in real time through the receiver’s speaker.
Authors:
Nirupam Roy and Romit Roy Choudhury, University of Illinois at Urbana–Champaign
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@inproceedings {194986,
author = {Nirupam Roy and Romit Roy Choudhury},
title = {Ripple II: Faster Communication through Physical Vibration},
booktitle = {13th USENIX Symposium on Networked Systems Design and Implementation (NSDI 16)},
year = {2016},
month = Mar,
isbn = {978-1-931971-29-4},
address = {Santa Clara, CA},
pages = {671--684},
url = {https://www.usenix.org/conference/nsdi16/technical-sessions/presentation/roy},
publisher = {USENIX Association},
}
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Abstract:
We envision physical vibration as a new modality of
data communication. In NSDI 2015, our paper reported
the feasibility of modulating the vibration of a smartphone’s
vibra-motor. When in physical contact with another
smartphone, the accelerometer of the second phone
was able to decode the vibrations at around 200 bits/s.
This paper builds on our first prototype, but redesigns
the entire radio stack to now achieve 30 kbps. The core
redesign includes (1) a new OFDM-based physical layer
that uses the microphone as a receiver (instead of the accelerometer),
and (2) a MAC layer that detects collision
at the transmitter and performs proactive symbol retransmissions.
We also develop two example applications on
top of the vibratory radio: (1) a finger ring that transmits
vibratory passwords through the finger bone to enable
touch based authentication, and (2) surface communication
between devices placed on the same table. The
overall system entails unique challenges and opportunities,
including ambient sound cancellation, OFDM over
vibrations, back-EMF based carrier sensing, predictive
retransmissions, bone conduction, etc. We call our system
Ripple II to suggest the continuity from the NSDI
2015 paper. We close the paper with a video demo that
streams music as OFDM packets through vibrations and
plays it in real time through the receiver’s speaker.
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