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Versions: 00

Internet Draft                                           M. Zeppelzauer
Intended status: Experimental                                 A. Ringot
Expires: September 2019                                 St. Poelten UAS
                                                          March 6, 2019




       SoniTalk: An Open Protocol for Data-Over-Sound Communication
                 draft-zeppelzauer-data-over-sound-00.txt


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   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Abstract

   This document defines a new protocol for communication via sound (and
   in particular via near-ultrasound) that is simple enough to be
   implemented on devices with limited computational resources, such as
   Internet-of-Things (IoT) devices.  The near-ultrasonic frequency band
   in the range of 18-22kHz represents a novel and so far hardly used
   channel for the communication of different devices, such as mobile
   phones, computers, TVs, personal assistants, and potentially a wide
   range of IoT devices.  Moreover, data-over-sound enables to connect
   low-end hardware devices to the Internet by near field communication
   with other Internet-connected devices.  Data-over-sound requires only
   a standard loudspeaker and a microphone for communication, and thus
   has very low hardware requirements compared to other communication
   standards such as Bluetooth, WLAN and NFC.  "SoniTalk" is designed as
   an open and transparent near-ultrasonic data transmission protocol
   for data-over-sound.  This document provides a specification of the
   protocol at the lowest layer (physical layer) in the sense of the OSI
   model.

Table of Contents


   1. Introduction...................................................2
   2. Details........................................................3
   3. Security Considerations........................................6
   4. IANA Considerations............................................7
   5. Conclusions....................................................7
   6. References.....................................................7
      6.1. Normative References......................................7
      6.2. Informative References....................................7
   7. Acknowledgments................................................7
   Authors' Addresses................................................9

1. Introduction

   The typical frequency band for data-over-sound starts at 18kHz.  This
   band can be corrupted by noise from the environment, which requires a
   number of counter measures to ensure a robust signal transmission.
   Especially the temporally varying characteristics of the channel
   makes the transmission of messages over longer time-spans more likely
   to be corrupted.  The proposed protocol tries to mitigate these
   sources of error by including redundancy in the encoding.  Redundancy


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   is generated by encoding each bit in terms of a Manchester code with
   a transition from high to low (and vice versa) for bit 1 and 0,
   respectively.  This type of redundancy makes the code not only more
   robust, but also enables a simpler decoding of the message.  To
   minimize the temporal message duration and maximize data rate,
   information is sent in multiple channels in parallel.



2. Details

   Data in the protocol is represented by individual messages.  Each
   message is represented by an acoustic signal that encodes the
   information contained in the message.  A message has a temporal and a
   spectral dimension, i.e., a two-dimensional layout in terms of
   frequency and time (see Figure 1).  Along the temporal dimension, a
   message is composed of several consecutive blocks.  Each message
   starts with a "start block", followed by M "message blocks" and an
   "end block".  Each message block has a duration of D ms.  The start-
   and end blocks have a duration of D/2 ms.  Each block spans multiple
   carrier frequencies Fi, where Fi in {F1, F2, ... ,FC} are C equally-
   spaced carrier frequencies covering a frequency band of B = FC-F1 Hz.
   The spacing of the frequencies is S = B/(C-1) Hz.  Each bit in the
   message can be addressed by a block number and carrier frequency.
   This layout allows for sending information in parallel on multiple
   frequencies.

   Information is encoded binary.  Each message block encodes one bit at
   each carrier frequency Fi.  For a logical "1" the amplitude of the
   first D/2 ms at frequency Fi of the block is "high" and the amplitude
   of the second D/2 ms is zero.  For a logical "0" the opposite is the
   case, i.e., the amplitude of the first D/2 ms at carrier frequency Fi
   of the block is zero and the amplitude of the second D/2 ms is
   "high".  The magnitude of "high" amplitude is not normative and
   depends on the actual use case, employed hardware and the targeted
   transmission range.

   The binary message content is encoded across the carrier frequencies
   (from lowest to highest frequency, i.e. F1 to FC) starting with the
   first message block, i.e. the first bit is encoded at message block 1
   and carrier frequency F1, the second bit is located at message block
   2 and carrier frequency F2, etc.

   Between two message blocks and in the middle of each block (i.e.
   after the first D/2 ms of a message block) a pause can be inserted of
   duration P with P >= 0.  For a pause, the sending amplitude is set to



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   zero.  The overall message duration is thus: D/2 + P + D*M + P*(2*M-
   1) + P + D/2 = D*(M+1) + P(2*M+1) ms.

   The first and last blocks of a message represent the start- and end
   blocks.  Start and end blocks are represented by the following
   encoding: a start block has "high" amplitude at the higher C/2
   frequencies (C/2 rounded up in case C is an odd number) and zero
   amplitude at the remaining frequencies.  For the end blocks the
   opposite is the case, i.e. "high" amplitude is present at the lower
   C/2 (C/2 rounded down) carrier frequencies and zero amplitude for the
   remaining frequencies.

   From the above specification it follows that the number of bits that
   can be represented by a message is: M*C.  The theoretical maximal
   data rate corresponds to 1000 / (D*(M+1) + P*(2*M+1)) * (M*C) bits
   per second.

   The schematic two-dimensional spectro-temporal layout (time at the x-
   axis and frequency on the y-axis) of a message for parameters:

      M=4 blocks,

      C=8 frequencies,

      D=2 (corresponding to the spacing of 2 characters along the
   temporal axis: "--"),

      P=4 (corresponding to the spacing of 4 characters along the
   temporal axis: "----"),

   encoding the following binary information:

      "01010011 01101111 01101110 01101001"

   is provided in the following.  Character "+" indicates "high"
   amplitude and "0" indicates zero amplitude.  Pause periods are
   indicated with the following pattern "...." for better visibility:












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   +--------------------------------------------------------------+
   |    ^                                                         |
   |    |     -------------------------------------------------   |
   |  f | F8 | +....+....0....+....0....0....+....+....0....0 |   |
   |  r | F7 | +....+....0....+....0....+....0....0....+....0 |   |
   |  e | F6 | +....0....+....+....0....+....0....0....+....0 |   |
   |  q | F5 | +....0....+....+....0....+....0....+....0....0 |   |
   |  u | F4 | 0....+....0....0....+....0....+....0....+....+ |   |
   |  e | F3 | 0....0....+....+....0....+....0....1....0....+ |   |
   |  n | F2 | 0....+....0....+....0....+....0....1....0....+ |   |
   |  c | F1 | 0....0....+....0....+....0....+....0....+....+ |   |
   |  y |     -------------------------------------------------   |
   |    |                                                         |
   |    |    start  message   message   message   message  end    |
   |    |    block  block 1   block 2   block 3   block 4 block   |
   |    |                                                         |
   |    ------------------------------------------------------->  |
   |                                                      time    |
   +--------------------------------------------------------------+

      Figure 1 The spectro-temporal layout of a single message, "msg"

   Note, the first eight bits of the message are encoded by the first
   half of message block 1 from low to high frequency.  The second half
   of message block 1 represents the inverted information.  The second
   eight bits are encoded in the first half of message block 2 from low
   to high frequency, etc.

   Different profiles (configurations) of the protocol can be defined to
   adapt it to the specific requirements of the respective use-cases.
   The definition of a profile requires the following information:

      D: the duration of a bit (i.e. a message block) in ms

      P: the pause period in ms

      F1: the lowest frequency in Hz

      C: the number of frequencies

      S: the spacing between successive frequencies Fi and Fi+1 in Hz

      M: the number of message blocks






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3. Security Considerations

   This specification is targeting solely the physical layer of the
   protocol.  Thus SoniTalk itself provides no communications security,
   and therefore a large number of attacks are possible including replay
   attacks, sniffing, eavesdropping, denial of service attacks, message
   destruction and message insertion.  A passive attack is sufficient to
   recover the binary information of messages transmitted with SoniTalk.
   No endpoint authentication is provided by the protocol as this
   definition only targets the physical layer.  Sender jamming is
   trivial, and therefore making messages unreadable is trivial.
   Attacks are however limited to the local environment around the
   communicating parties (usually within a few meters).  If the
   communication takes place in a room, possible attacks are most likely
   successful from inside the room and unlikely from outside the room as
   near-ultrasonic signals hardly pass through walls.

   Unlikely attacks are message deletion and message modification as
   this would require to acoustically manipulate the message while it is
   sent over the air.  While it cannot be guaranteed with absolute
   certainty such attacks would be extremely difficult, e.g. sending
   interference sound to cancel out a message acoustically.  Furthermore
   acoustically modifying individual bits of a message for message
   modification would require precise timing and would very likely
   destroy the integrity of the message since the acoustic overlay would
   introduce interferences.

   To ensure data integrity the use of an error detecting (e.g. a CRC
   code) or an error correcting code is highly recommended when encoding
   the message.  To establish, confidentiality the binary message should
   further be encrypted, e.g. by a symmetric or asymmetric encryption
   scheme where the keys should be exchanged over an out-of-band channel
   (e.g. Bluetooth).  Peer entity authentication is also not implemented
   at the physical layer and needs to be provided at a higher layer.

   It is the particular duty of the developers of applications using the
   protocol to comprehensively inform the user about the near-ultrasonic
   data exchange (both sending and receiving) and moreover to inform the
   users when personal information is sent over the protocol.

   Particular care has to be taken in selecting the carrier frequencies
   for the data transmission so that no actively or passively
   participating party is disturbed by potential hearable artifacts of
   the acoustic data transmission.  This in particular includes children
   as well as animals in the environment.




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4. IANA Considerations

   This document has no actions for IANA.

5. Conclusions

   This internet draft introduces SoniTalk, which is the first open
   protocol for acoustic near field communication via the near-
   ultrasonic band.  Near-ultrasound communication represents an
   alternative and complement to other existing near-field communication
   protocols, such as Bluetooth, radio-based NFC and WLAN and is
   particularly well-suited for IoT devices thanks to its low hardware
   requirements.  This document specifies the protocol at the physical
   layer and thus primarily focuses on the definition of the message
   structure for information exchange.  Extensions on top of this layer
   are subject to future specification efforts.



6. References

6.1. Normative References

6.2. Informative References

   [1]   Hubert Zimmermann, OSI Reference Model - The ISO Model of
         Architecture for Open Systems Interconnection, IEEE
         Transactions on Communications, vol. 28, no. 4, April 1980, pp.
         425-432

7. Acknowledgments

   The work which led to this protocol specification was funded by
   netidee Open Innovations of the Internet Foundation Austria.

   This document was prepared using 2-Word-v2.0.template.dot.













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Appendix A.                 Scope and Remarks

 A.1. Remarks

   It is recommended to split the M*C bits of a message into E parity
   bits for error detection and error correction and M*C-E bits for the
   payload of the message.  The size of the parity information is not
   normative and depends on the actual application (e.g. environmental
   conditions etc.)

   The message length is fixed and must not vary.  In case the specified
   message length is longer than the actual information to be sent, the
   remaining bits must be filled (e.g. by some special symbol) to comply
   with the protocol specifications.

 A.2. Out of Scope

   The spacing of carrier frequencies, the actual height of the
   frequencies, the pause duration P inside a message as well as the
   spacing between successive messages is not part of this
   specification.

   This protocol specification focuses exclusively on the lowest network
   layer (i.e. physical layer according to the OSI reference model [1]).
   A protocol for distributing information across several messages,
   session handling, addressing, error detection and correction as well
   as synchronous and asynchronous communication is beyond this
   specification and subject to future norming initiatives.





















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Appendix B.                 Comments and Feedback

   Please address all comments, discussions, and questions to
   matthias.zeppelzauer@fhstp.ac.at



Authors' Addresses

   Matthias Zeppelzauer
   St. Poelten University of Applied Sciences
   Matthias Corvinus-Strasse 15, 3100 St. Poelten
   Austria

   Email: matthias.zeppelzauer@fhstp.ac.at

   Alexis Ringot
   St. Poelten University of Applied Sciences
   Email: alexis.ringot@fhstp.ac.at






























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