OTFS methods of data channel characterization and uses thereof

US 9,867,065 B2
Filed: 09/12/2016
Issued: 01/09/2018
Est. Priority Date: 05/28/2010
Status: Active Grant

First Claim

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1. A receiver apparatus, comprising:

a memory,a processor; and

a network interface;

wherein the processor reads instructions from the memory and implements an automated method of acquiring a 2D channel state of an impaired data channel connecting at least one transmitter and the receiver via the network interface,said impaired data channel comprising at least one reflector, each said at least one reflector comprising a reflector location, reflector frequency shift, and at least one reflector coefficients of reflection;

the transmitter comprising a transmitter location and transmitter frequency shift;

the receiver comprising a receiver location and receiver frequency shift;

wherein said 2D channel state comprises information pertaining to relative locations, frequency shifts, and reflector coefficients of reflection of said transmitter, the receiver, and reflectors;

wherein the transmitter transmits direct orthogonal time frequency space (OTFS) pilot bursts, said direct OTFS pilot bursts comprising a plurality of OTFS pilot symbols P_pt,pftransmuted as OTFS pilot symbol waveform bursts P_pt,pf·

W_p(pt, pf), over a plurality of combinations of times pt and frequencies pf, where each said pt and pf are unique pilot time-frequency coordinates chosen from a two dimensional pilot OTFS time-frequency grid, and all said OTFS pilot symbol waveform bursts P_pt,pf·

W_p(pt, pf) are mutually orthogonal waveform bursts derived from cyclically time and frequency shifted versions of a same OTFS pilot basis waveform W_p;

said instructions comprising;

instructions for receiving at least said pilot bursts according to at least a two dimensional pilot OTFS time-frequency bin structure with bin sizes and bin-coordinate positions proportional to said OTFS time-frequency grid;

wherein upon propagation through said impaired data channel, said direct OTFS pilot bursts then travel over at least one path, said at least one path comprising at least one of;

a;

direct OTFS pilot bursts traveling directly from said transmitter to said receiver; and

b;

replica OTFS pilot bursts comprising direct OTFS pilot bursts that have reflected off of said at least one reflector before reaching said receiver, thereby producing direct OTFS waveform bursts that are further reflector time-delayed and reflector frequency-shifted at said receiver;

wherein at said receiver, a resulting combination of any said transmitter frequency shifted and receiver frequency shifted direct OTFS pilot bursts and any said replica OTFS pilot bursts produces channel-convoluted OTFS pilot bursts;

the instructions further comprising;

instructions for, at said at least one receiver, using said bin structure to receive said channel-convoluted OTFS pilot bursts and to determine said 2D channel state of said impaired data channel connecting said transmitter and said receiver.

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Abstract

Fiber, cable, and wireless data channels are typically impaired by reflectors and other imperfections, producing a channel state with echoes and frequency shifts in data waveforms. Here, methods of using OTFS pilot symbol waveform bursts to automatically produce a detailed 2D model of the channel state are presented. This 2D channel state can then be used to optimize data transmission. For wireless data channels, an even more detailed 2D model of channel state can be produced by using polarization and multiple antennas in the process. Once 2D channel states are known, the system turns imperfect data channels from a liability to an advantage by using channel imperfections to boost data transmission rates. The methods can be used to improve legacy data transmission modes in multiple types of media, and are particularly useful for producing new types of robust and high capacity wireless communications using non-legacy OTFS data transmission methods.

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20 Claims

1. A receiver apparatus, comprising:
- a memory,a processor; and
  
  a network interface;
  
  wherein the processor reads instructions from the memory and implements an automated method of acquiring a 2D channel state of an impaired data channel connecting at least one transmitter and the receiver via the network interface,said impaired data channel comprising at least one reflector, each said at least one reflector comprising a reflector location, reflector frequency shift, and at least one reflector coefficients of reflection;
  
  the transmitter comprising a transmitter location and transmitter frequency shift;
  
  the receiver comprising a receiver location and receiver frequency shift;
  
  wherein said 2D channel state comprises information pertaining to relative locations, frequency shifts, and reflector coefficients of reflection of said transmitter, the receiver, and reflectors;
  
  wherein the transmitter transmits direct orthogonal time frequency space (OTFS) pilot bursts, said direct OTFS pilot bursts comprising a plurality of OTFS pilot symbols P_pt,pftransmuted as OTFS pilot symbol waveform bursts P_pt,pf·
  
  W_p(pt, pf), over a plurality of combinations of times pt and frequencies pf, where each said pt and pf are unique pilot time-frequency coordinates chosen from a two dimensional pilot OTFS time-frequency grid, and all said OTFS pilot symbol waveform bursts P_pt,pf·
  
  W_p(pt, pf) are mutually orthogonal waveform bursts derived from cyclically time and frequency shifted versions of a same OTFS pilot basis waveform W_p;
  
  said instructions comprising;
  
  instructions for receiving at least said pilot bursts according to at least a two dimensional pilot OTFS time-frequency bin structure with bin sizes and bin-coordinate positions proportional to said OTFS time-frequency grid;
  
  wherein upon propagation through said impaired data channel, said direct OTFS pilot bursts then travel over at least one path, said at least one path comprising at least one of;
  
  a;
  
  direct OTFS pilot bursts traveling directly from said transmitter to said receiver; and
  
  b;
  
  replica OTFS pilot bursts comprising direct OTFS pilot bursts that have reflected off of said at least one reflector before reaching said receiver, thereby producing direct OTFS waveform bursts that are further reflector time-delayed and reflector frequency-shifted at said receiver;
  
  wherein at said receiver, a resulting combination of any said transmitter frequency shifted and receiver frequency shifted direct OTFS pilot bursts and any said replica OTFS pilot bursts produces channel-convoluted OTFS pilot bursts;
  
  the instructions further comprising;
  
  instructions for, at said at least one receiver, using said bin structure to receive said channel-convoluted OTFS pilot bursts and to determine said 2D channel state of said impaired data channel connecting said transmitter and said receiver.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 2. The receiver of claim 1, wherein prior to transmission, said plurality of OTFS pilot symbols P_pt,pf, and two dimensional pilot OTFS time-frequency grid and bin structure are chosen so that if, after transmission by said transmitter, said impaired data channel subsequently causes at least some of said OTFS pilot symbol waveform bursts P_t1,f1W_p(t1, f1) originally transmitted at a first time-frequency coordinate to be projected onto different OTFS pilot symbol waveform bursts P_t2,f2Wp(t2, f2) originally transmitted at a different time-frequency coordinate, and bins different from those nominally corresponding to said OTFS pilot symbol waveform bursts P_t1,f1W_p(t1, f1), at least some of said projections will be detectable and quantifiable by said receiver.
  - 3. The receiver of claim 2, wherein said plurality of OTFS pilot symbols P_pt,pftransmitted as OTFS pilot symbol waveform bursts P_pt,pfW_p(pt, pf) comprise at least one non-null OTFS pilot symbol P_pt,pftransmitted as an OTFS pilot symbol waveform burst P_pt,pfW_p(pt, pf) with sufficient power to be detectable by said receiver;
    - and any of;
      
      1;
      
      at least some of said plurality of OTFS pilot symbols are null pilot symbols intended to create empty pt and pf unique pilot time-frequency coordinates chosen from said two dimensional pilot OTFS time-frequency grid, where no waveform burst is transmitted;
      
      or2;
      
      at least some of said plurality of OTFS pilot symbols are background pilot symbols intended to create a uniform background of pt and pf unique pilot time-frequency coordinates chosen from said two dimensional pilot OTFS time-frequency grid to enable projections of channel-convoluted non-null OTFS pilot bursts onto said uniform background to be detectable and quantifiable by said receiver.
  - 4. The receiver of claim 1, wherein said 2D channel state is at least partially determined by using at least one 2D impulse response to mathematically describe how said impaired data channel causes at least some of said OTFS pilot symbol waveform bursts P_t1,f1W_p(t1, f1) transmitted at a first time-frequency coordinate to be projected onto different OTFS pilot symbol waveform bursts P_t2,f2W_p(t2, f2) originally transmitted at a different time-frequency coordinate, and bins different from those nominally corresponding to said OTFS pilot symbol waveform bursts P_t1,f1W_p(t1, f1).
  - 5. The receiver of claim 4, further using a plurality of said 2D impulse responses from a plurality of said bins to at least partially describe said 2D channel state as at least one 2D transform comprising at least one of a 2D Z-transform or other 2D transform.
  - 6. The receiver of claim 1, wherein said plurality of OTFS pilot symbols P_pt,pfare known by said receiver, and wherein said plurality of OTFS pilot symbols are further chosen to be any of:
    - one or two dimensional m-sequences comprising binary maximal-length shift register sequences, delta values P_i,jsurrounded by regions of P_pt,pfzero values, one or two dimensional Barker codes, Costas arrays, Walsh matrixes, or other plurality of pilot symbols selected to facilitate acquiring said 2D channel state; and
      
      wherein said bins have time-frequency resolutions that are equal to or more precise than time-frequency resolutions of said grid.
  - 7. The receiver of claim 1, further receiving a plurality of data symbols through said impaired data channel transmitted by said transmitter as direct data bursts comprising a plurality of data carrying waveform bursts, and to receive said direct data bursts along with said direct OTFS pilot bursts to said at least one receiver;
    - wherein said direct data bursts also are reflected off of said at least one reflector, thereby producing replica data bursts comprising time-delayed and reflector frequency-shifted direct data bursts at said receiver, and wherein at said receiver, a resulting combination of any said transmitter frequency shifted and receiver frequency shifted direct data bursts, and replica data bursts, produce channel-convoluted data bursts;
      
      wherein the instructions further include;
      
      instructions for using said 2D channel state to deconvoluting at least some of said channel-convoluted data bursts at said at least one receiver, thereby deriving at least an approximation of said plurality of data symbols.
  - 8. The receiver of claim 1, wherein said impaired data channel is an optical fiber data channel comprising at least one optical fiber, an electrically conducting wire data channel comprising at least one metallic electrical conductor, or a data channel comprising a fluid.
  - 9. The receiver of claim 1, wherein said impaired data channel is a wireless data channel, said transmitter is a wireless transmitter, said receiver is a wireless receiver, said reflector is a wireless reflector further comprising a reflector velocity, said reflector frequency shift is a receiver velocity Doppler shift, and said at least one reflector coefficient of reflection is a reflector coefficient of wireless reflection;
    - said transmitter has a transmitter velocity, and said transmitter frequency is at least partially determined by a transmitter Doppler shift that varies according to said transmitter velocity;
      
      said receiver has a receiver velocity, and said receiver frequency is at least partially determined by a receiver Doppler shift that varies according to said receiver velocity;
      
      said direct OTFS pilot bursts comprise a plurality of wireless OTFS pilot symbol waveform bursts; and
      
      wherein, said 2D channel state comprises information pertaining to relative locations, velocities, velocity induced frequency shifts caused by transmitter Doppler shifts;
      
      receiver Doppler shifts, reflector Doppler shifts, and reflector coefficients of reflection of said at least one transmitters, receivers, and reflectors.
  - 10. The receiver of claim 9, wherein said direct data bursts also are reflected off of said at least one wireless reflector, thereby producing replica data bursts comprising direct data bursts that are further reflector time-delayed and reflector velocity Doppler-shifted at said at least one wireless receiver, and wherein at said receiver, a resulting combination of any said transmitter Doppler-shifted and receiver Doppler-shifted direct data bursts and replica data bursts produce channel-convoluted data bursts;
    - the instructions further comprising;
      
      instructions for using said 2D channel state to furtherb) deconvoluting at least some of said channel-convoluted data bursts at said at least one wireless receiver, thereby deriving at least an approximation of said plurality of data symbols;
      
      wherein said data symbols and wireless data carrying waveform bursts conform to any of TDMA, GSM, FDMA, OFDM, CDMA, OTFS wireless waveform bursts, or other types of wireless waveform bursts.
  - 11. The receiver of claim 10, wherein said deconvoluting is done by using at least one 1D projection of said 2D channel state along any of a time axis, frequency axis, or time-frequency axis.
  - 12. The receiver of claim 10, wherein said direct OTFS pilot bursts include polarized direct OTFS pilot bursts comprising polarized wireless OTFS pilot symbol waveform bursts according to at least one polarization direction;
    - said at least one wireless reflector is a polarization altering wireless reflector that alters a polarization direction of its reflected wireless OTFS waveform bursts according to a first reflector polarization operator, thereby producing replica polarized OTFS pilot bursts that comprise polarization shifted time-delayed and reflector Doppler-shifted replicas of said polarized direct OTIS pilot bursts;
      
      said at least one wireless receiver is further configured to detect a direction of polarization in its received wireless waveforms; and
      
      wherein at said wireless receiver, a resulting combination of any said transmitter Doppler-shifted, receiver Doppler-shifted, and receiver polarized direct OTFS pilot bursts and replica polarized OTFS pilot bursts produce channel-convoluted polarized OTFS pilot bursts;
      
      the instructions further including;
      
      instructions for receiving said channel-convoluted polarized OTFS pilot bursts and detecting their direction of polarization; and
      
      instructions for further using said direction of polarization of said channel-convoluted polarized OTFS pilot bursts to further determine said 2D channel state of said impaired data channel.
  - 13. The receiver of claim 10, wherein said direct data bursts are direct OTFS data bursts comprising OTFS data symbols transmitted by OTFS wireless data symbol waveform bursts;
    - said wireless receiver configured to simultaneously receive, over a same frequency range, at most T streams of stream identifiable direct OTFS data and pilot bursts, each stream identifiable direct OTFS data and pilot bursts having at least OTFS pilot symbols P_s,pt,pffurther chosen to be stream identifiable;
      
      wherein said wireless receiver has R uniquely configured receiving antennas, both T and R being greater than 1, and R being greater than or equal to T;
      
      wherein at said at least one wireless receiver antenna R_a, a resulting combination of any said transmitter Doppler-shifted and receiver Doppler-shifted stream identifiable direct OTFS data and pilot bursts, and replica stream identifiable direct OTFS data and pilot bursts, produce receiving antenna specific channel-convoluted stream identifiable OTFS data and pilot bursts;
      
      the instructions comprising;
      
      instructions for, for each wireless receiving antenna R and each stream identifiable plurality of OTFS pilot symbol waveforms, determining said 2D channel state at said receiving antenna, thereby determining stream specific 2D channel states, and use said stream specific 2D channel state forb) deconvoluting at least some of said antenna specific channel-convoluted stream identifiable OTFS data and pilot bursts at said at least one receiver, thereby deriving at least an approximation of said plurality of data symbols.
  - 14. The receiver of claim 13, wherein the instructions for determining said 2D channel state further include:
    - instructions for using at least one 2D impulse response to mathematically describe how, for said stream identifiable direct OTFS data and pilot bursts, stream-1 CATS pilot symbol waveform bursts P_s1,t1,f1Wp(t1,f1) transmitted at a first time-frequency coordinate to be projected onto different stream-2 OTFS pilot symbol waveform bursts P_s2,t2,f2Wp(t2,f2) originally transmitted at a different time-frequency coordinate, and bins different from those normally corresponding to said stream 1 OTFS pilot symbol waveform bursts P_s1,t1,f1Wp(t1,f1), according to a receiving antenna specific aspect of said impaired data channel, thereby determining, for each stream, R receiving antenna specific 2D impulse responses; and
      
      instructions for using said R receiving antenna specific 2D impulse responses to either precode said streams at said transmitter, or deconvolute said receiving antenna specific channel-convoluted stream identifiable OTFS data and pilot bursts.
  - 15. The receiver of claim 13, wherein said at least one wireless reflector is a polarization altering wireless reflector that alters a polarization direction of its reflected wireless OTFS waveform bursts according to a first reflector polarization operator, thereby producing polarized stream identifiable replica OTFS data and pilot bursts comprising polarization shifted time-delayed and reflector Doppler-shifted replicas of said polarized stream identifiable direct OTFS data and pilot bursts;
    - said receiver has at least some of its R uniquely configured receiving antennas configured to detect a direction of polarization in its received wireless waveforms;
      
      wherein at said receiver, a resulting combination of any said transmitter Doppler-shifted and receiver Doppler-shifted polarized stream identifiable direct OTFS data and pilot bursts; and
      
      polarized stream identifiable replica OTFS data and pilot bursts, produce antenna specific channel-convoluted stream identifiable polarized OTFS data and pilot bursts;
      
      the instructions including;
      
      instructions for further using at least some of said receiver'"'"'s R uniquely configured receiving antennas to receive and detect the direction of polarization of said antenna specific channel-convoluted stream identifiable polarized OTFS data and pilot bursts;
      
      instructions for, for each wireless receiving antenna R_aand each stream identifiable plurality of OTFS pilot symbol waveforms, determining said 2D channel state at said receiving antenna R_a, and using said 2D channel states fordeconvoluting at least some of said antenna specific channel-convoluted stream identifiable polarized OTFS data and pilot bursts at said at least one receiver, thereby deriving at least an approximation of said plurality of data symbols.
  - 16. The receiver of claim 13, wherein said 2D channel state and said deconvoluting is used to shape a spatial directionality of the wireless waveforms received by said R uniquely configured receiving antennas.
  - 17. The receiver of claim 16, wherein the instructions further include:
    - Instructions for achieving said spatial directionality of the wireless waveforms received by said R uniquely configured receiving antennas by monitoring the relative phases or angles of the wireless waveforms received by said R uniquely configured receiving antennas.
  - 18. The receiver of claim 13, wherein said at most T different streams are carried by commonly shared OTFS carrier waveforms over a same ranges of times and frequencies.
  - 19. The receiver of claim 13, wherein each said stream identifiable direct OTFS data and pilot bursts are not antenna identifiable and not antenna specific.
  - 20. The receiver of claim 13, wherein said stream identifiable direct OTFS data and pilot bursts are antenna identifiable and antenna specific.

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Current Assignee
Cohere Technologies Inc
Original Assignee
Cohere Technologies Inc
Inventors
Hadani, Ronny, Rakib, Shlomo Selim
Primary Examiner(s)
Elliott, IV, Benjamin H

Application Number

US15/263,103
Publication Number

US 20160381576A1
Time in Patent Office

484 Days
Field of Search
US Class Current
CPC Class Codes

H04B 1/692   Hybrid techniques using com...

H04B 7/0626   Channel coefficients, e.g. ...

H04B 7/10   Polarisation diversity; Dir...

H04L 25/0212   of impulse response

H04L 25/0226   sounding signals per se

H04L 27/366   Arrangements for compensati...

H04L 5/0007   the frequencies being ortho...

H04L 5/0048   Allocation of pilot signals...

H04W 24/02   Arrangements for optimising...

OTFS methods of data channel characterization and uses thereof

First Claim

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Abstract

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20 Claims

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OTFS methods of data channel characterization and uses thereof

First Claim

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Accused Products

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Abstract

19 Citations

20 Claims

Specification

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Solutions

Use Cases

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