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WO2015023801A1 - Système d'antenne et procédé de transmission sans fil en duplex intégral avec chiffrement basé sur la phase de canal - Google Patents

Système d'antenne et procédé de transmission sans fil en duplex intégral avec chiffrement basé sur la phase de canal Download PDF

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Publication number
WO2015023801A1
WO2015023801A1 PCT/US2014/050968 US2014050968W WO2015023801A1 WO 2015023801 A1 WO2015023801 A1 WO 2015023801A1 US 2014050968 W US2014050968 W US 2014050968W WO 2015023801 A1 WO2015023801 A1 WO 2015023801A1
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WO
WIPO (PCT)
Prior art keywords
signal
antenna element
active antenna
frequency
channel
Prior art date
Application number
PCT/US2014/050968
Other languages
English (en)
Inventor
Amir Khandani
Original Assignee
Invention Mine Llc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Invention Mine Llc filed Critical Invention Mine Llc
Priority to EP14836322.9A priority Critical patent/EP3033806A4/fr
Priority to CA2921045A priority patent/CA2921045A1/fr
Publication of WO2015023801A1 publication Critical patent/WO2015023801A1/fr

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q19/00Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
    • H01Q19/28Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using a secondary device in the form of two or more substantially straight conductive elements
    • H01Q19/30Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using a secondary device in the form of two or more substantially straight conductive elements the primary active element being centre-fed and substantially straight, e.g. Yagi antenna
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/52Means for reducing coupling between antennas; Means for reducing coupling between an antenna and another structure
    • H01Q1/521Means for reducing coupling between antennas; Means for reducing coupling between an antenna and another structure reducing the coupling between adjacent antennas
    • H01Q1/525Means for reducing coupling between antennas; Means for reducing coupling between an antenna and another structure reducing the coupling between adjacent antennas between emitting and receiving antennas
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q15/00Devices for reflection, refraction, diffraction or polarisation of waves radiated from an antenna, e.g. quasi-optical devices
    • H01Q15/14Reflecting surfaces; Equivalent structures
    • H01Q15/148Reflecting surfaces; Equivalent structures with means for varying the reflecting properties
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/44Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the electric or magnetic characteristics of reflecting, refracting, or diffracting devices associated with the radiating element
    • H01Q3/446Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the electric or magnetic characteristics of reflecting, refracting, or diffracting devices associated with the radiating element the radiating element being at the centre of one or more rings of auxiliary elements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L9/00Cryptographic mechanisms or cryptographic arrangements for secret or secure communications; Network security protocols
    • H04L9/08Key distribution or management, e.g. generation, sharing or updating, of cryptographic keys or passwords
    • H04L9/0861Generation of secret information including derivation or calculation of cryptographic keys or passwords
    • H04L9/0863Generation of secret information including derivation or calculation of cryptographic keys or passwords involving passwords or one-time passwords
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L2209/00Additional information or applications relating to cryptographic mechanisms or cryptographic arrangements for secret or secure communication H04L9/00
    • H04L2209/80Wireless

Definitions

  • the present disclosure relates to security in wireless communications.
  • the present disclosure relates to systems and methods to use a two-way (full-duplex) link to establish a secret key, or to enhance the security.
  • Full-duplex communications is used in many telecommunications technologies, e.g., ordinary wired telephones, Digital Subscriber Line (DSL), wireless with directional antennas, free space optics, and fiber optics.
  • DSL Digital Subscriber Line
  • the impact of full-duplex links in these earlier applications is limited to doubling the rate by providing two symmetrical pipes of data flowing in opposite directions. This affects the point-to-point throughput with no direct impact on networking and security issues.
  • security protocols are needed to access the public channels.
  • full-duplex is currently used for example in wireless systems with highly directional antennas or free space optics
  • the underlying full-duplex radios are essentially nothing but two independent half-duplex systems separated in space.
  • the general two-way channel is very difficult to realize in wireless communications due to excessive amounts of self- interference, i.e., the interference each transmitter generates for the receiver(s) in the same node.
  • full-duplex Other prior art techniques to provide a type communication system that might be referred to as full-duplex are really frequency division duplex (FDD), where separate frequency ranges are used in the transmit and receive (uplink/downlink) directions.
  • FDD frequency division duplex
  • full-duplex is intended to refer to simultaneous transmission and reception of signals within the same frequency band.
  • An antenna apparatus includes a first active antenna element having a propagation characteristic.
  • the first active antenna element may be a dipole antenna.
  • a plurality of radio- frequency reflectors are positioned around the first active antenna element.
  • a plurality of switchable radio-frequency reflectors positioned around the first active antenna element and are configured to perturb the propagation characteristic.
  • each of the plurality of switchable radio-frequency reflectors includes an array of interconnected conductive elements, where the conductive elements are interconnected by one or more radio-frequency switches.
  • the interconnected conductive elements may be planar conductive elements.
  • the array of interconnected conductive elements is a one- dimensional array having the conductive elements serially connected by the radio-frequency switches.
  • the radio-frequency switches may be PIN diodes.
  • the first plurality of switchable radio-frequency refiectors may be arranged in a substantially cylindrical array around the first active antenna element.
  • the plurality of radio-frequency reflectors are be positioned in an interleaved configuration with respect to ones of the plurality of switchable radio-frequency refiectors.
  • the plurality of radio-frequency reflectors positioned around the first active antenna element may be positioned at a first radial distance from the first active antenna element, and the plurality of switchable radio-frequency refiectors may be positioned at a second radial distance from the first active antenna element.
  • the antenna apparatus may further include a second active antenna element, positioned within the plurality of radio-frequency refiectors and the plurality of switchable radio-frequency reflectors.
  • a propagation perturbation control circuit is connected to the plurality of switchable radio-frequency reflectors.
  • the propagation perturbation control circuit may be configured to selectively apply a voltage across ones of the switchable radio-frequency reflectors.
  • an antenna assembly in another embodiment, includes a first active antenna element and a first plurality of switchable radio -frequency reflectors positioned around at least the first active antenna element.
  • the assembly further includes a second active antenna element.
  • the first and second active antenna elements may be dipole antennas.
  • a transceiver is provided including transmit circuitry and receive circuitry.
  • the assembly further includes a crossbar switch selectable between (1) a first state in which the crossbar switch connects the first active antenna element to the transmit circuitry and the second active antenna element to the receive circuitry; and (2) a second state in which the crossbar switch connects the first active antenna element to the receive circuitry and the second active antenna element to the transmit circuitry.
  • Each of the switchable radio-frequency reflectors may include a plurality of conductive segments connected by one or more switching components.
  • the first plurality of switchable radio-frequency refiectors is positioned only around the first active antenna element. In such an embodiment, there may be a second plurality of switchable radio-frequency reflectors positioned around the second active antenna element. [0015] In an alternative embodiment, the first plurality of switchable radio-frequency reflectors is positioned around both the first active antenna element and the second active antenna element.
  • a method includes transmitting, from a first device to a second device, a first signal using a first active antenna element.
  • a second signal is received at the first device using a second active antenna element, where the second signal is generated by the second device in response to receiving the first signal.
  • the method further includes measuring at the first device a channel phase value based on a phase difference between the first signal and the second signal.
  • the first device receives a third signal using the first active antenna element, where the third signal is generated by the second device.
  • a fourth signal is transmitted from the first device to the second device using the second active antenna element, where the fourth signal generated based on the received third signal.
  • receiving the third signal includes demodulating the first incoming signal to generate a first demodulated signal
  • transmitting the fourth signal includes re-modulating the first demodulated signal to generate the fourth signal
  • FIG. 1 is a block diagram of a wireless communication system in accordance with some embodiments.
  • FIG. 2 depicts a phase masking operation.
  • FIG. 3 is a channel diagram of full-duplex transceivers in accordance with some embodiments.
  • FIG. 4 is a channel diagram of full-duplex transceivers in accordance with some alternative embodiments.
  • FIG. 5 shows schematic views of a first method for key exchange using channel reciprocity and thereby providing symmetry in the end-to-end 4-port network.
  • FIG. 6 shows a second method for key exchange, wherein eavesdropper in total listens to four transmissions, but also adds four unknowns (e.g. channel phase to their receive antenna(s)) and consequently cannot extract any useful information from such measurements.
  • eavesdropper in total listens to four transmissions, but also adds four unknowns (e.g. channel phase to their receive antenna(s)) and consequently cannot extract any useful information from such measurements.
  • FIGs. 7 and 8 show schematic views of a third method for key exchange based on cancelling self-interference and thereby providing symmetry in the end-to-end 4-port network
  • FIG. 9 shows a pictorial view for a first example of an RF-mirror used to reflect RF signals, in part, with methods for adjusting the level of reflection, i.e., tunable RF-mirror.
  • FIG. 10 shows pictorial views for a second example of a tunable RF-mirror.
  • FIG. 11 shows pictorial view for a third example of an on-off RF-mirror.
  • FIG. 12 shows a pictorial view for two examples of tunable RF chamber surrounding transmits and/or receive antenna.
  • FIG. 13 shows pictorial view for a high level description for cascading several analog interference cancellation stages.
  • FIG. 14 shows a more detailed view for cascading several analog interference cancellation stages.
  • FIG. 15 shows that, to reduce delay, the cascaded analog interference cancellations can be implemented in the time domain, wherein underlying filter structures can be computed by training in the frequency domain.
  • FIGs. 16 and 17 are block diagram of another embodiment of a self-cancellation full- duplex transceiver.
  • FIG. 18 shows the flow chart for the training to compute the filters used in the cascaded analog interference cancellation scheme.
  • FIG. 19 is a schematic diagram illustrating an antenna surrounded by objects with tunable RF properties.
  • FIGs. 20-23 show isometric views of pair- wise symmetrical antennas.
  • FIGs. 24-25 show a pictorial view of triple- wise symmetrical antenna structures.
  • FIGs. 26-28 show examples of MIMO antenna structures in 3-dimensional space.
  • FIG. 29 shows an example for the placement of one antenna set in the plane of symmetry of some other antenna(s) to support MIMO in 2-dimensions.
  • FIGs. 30-32 show examples of some antenna structures showing that the coupling between antennas can be very strong (-2dB) due to near field signals unless it is cancelled relying on pair- wise symmetry.
  • FIGs. 33 and 34 show numerical results (2.4Ghz band using HFSS) for one example of modifying the shape of the antenna.
  • FIGs. 35 and 36 show a schematic view of two pair- wise symmetrical antennas.
  • FIG. 37 is a schematic perspective view of an antenna assembly according to some embodiments.
  • FIG. 38 is a schematic perspective view of an antenna assembly according to some embodiments.
  • FIG. 39 is a schematic perspective view of an antenna assembly according to some embodiments.
  • FIG. 40 is a schematic block diagram of an antenna assembly connected to a transceiver.
  • FIG. 41 is a flow chart illustrating an exemplary method of operating an antenna assembly according to some embodiments.
  • FIG. 42 is a schematic illustration of an antenna assembly in accordance with some embodiments.
  • FIG. 43 is a schematic illustration of an antenna assembly in accordance with some embodiments.
  • FIG. 44 is a schematic illustration of a wall component in an antenna assembly in accordance with some embodiments.
  • wireless radios are considered to be inherently insecure as the signal transmitted by any given unit can be freely heard by eavesdroppers. This issue is due to the broadcast nature of wireless transmission. However, the same broadcast nature of wireless systems can contribute to enhancing security if nodes rely on two-way links. In this case, eavesdroppers hear the combination of the two signals transmitted by the two parties involved in a connection. Described herein are methods to enhance and benefit from this feature towards improving security.
  • the system 10 includes a user A (Alice) 16 communicating with user B (Bob 26) by way of wireless medium 12.
  • each user (or either one) is able to alter the wireless channel characteristics using various antenna configurations, including configurable reflectors, etc, shown by 14 and 24.
  • the users A and B each measure a round trip phase value ⁇ associated with the channel that is unique to their round trip transmission path 22, 28.
  • An eavesdropper 20 may overhear the transmissions, but it will be through a different channel through medium 18.
  • security enhancements are provided.
  • modulo 2 ⁇ addition of phase values occurring naturally in wireless wave propagation are used to mask several bits using Phase Shift Keying (PSK) modulation.
  • PSK Phase Shift Keying
  • a shared key is generated: in one symbol transmission, two nodes communicate one phase value using the channel between them. The exchange is repeated following a change in the channel for several rounds to generate several common phase values with which to define a sufficient key.
  • Changes in the overall RF channel are achieved by perturbing RF properties of the environment close to transmit and/or receive antennas.
  • RF mirrors may be used to change the path for the RF signal propagation. Having N such mirrors enables to extract 2 N phase values.
  • antenna structures are connected to both transmit and receive chains (i.e. to transmit in one interval and receive in another) and in another embodiment, corrective signal injection is used to cancel self- interference and such that antenna structures need not be connected to both transmit and receive chains. Further operations may be performed to further enhance the security. This includes using the methods described herein as an enhancement to conventional methods of cryptography, or as a tool to enhance and realize information theoretical security.
  • a common method in security is based on bit-wise masking (modulo 2 addition) of a key (sequence of bits) with the message to be transmitted, which can be easily reversed if the two parties have access to a common key.
  • the only provably secure system is the so-called Vernam Cipher, which is based on using such a key only once.
  • Teachings herein observe and exploit the point that an operation similar to bit masking (binary addition modulo two, or XOR) occurs naturally in RF transmission in the sense that the received phase is the sum (modulo 2 ⁇ ) of the transmitted phase and the channel phase.
  • a conventional Vernam Cipher is based on having a mask like Z which is known at the two legitimate parties and the message X is added modulo two (XOR) to the mask Z, and this XOR operation can be reversed at the receiver end by using the same mask.
  • module 2 addition can be generalized to 2 ⁇ addition of phase values, while maintaining similar independence and security properties
  • modulo 2 ⁇ addition of phase values occurs naturally as the wireless wave propagates, and consequently, it can be used to mask several bits using Phase Shift Keying (PSK) modulation.
  • PSK Phase Shift Keying
  • any eavesdropper will hear the PSK symbol with a different mask phase that is due to a different channel, namely the channel between transmitter and eavesdropper.
  • Each eavesdropper antenna results in a new observation, but also introduces a new phase mask which is again uniform between zero to 2 ⁇ and masks the information embedded in the transmit phase.
  • an eavesdropper will not be able to extract any useful information, regardless of its signal-to-noise ratio and number of antennas.
  • An obstacle in some prior art techniques in exploiting common randomness to generate a shared key is to find a method to deal with possible errors in the shared values and consolidate the corresponding information to a smaller piece without error.
  • the masks at the transmitter and at the receiver do not need to be exactly the same as small discrepancies between them can be corrected relying on the underlying channel code.
  • Symmetrical antenna structures and multiple stages of canceling self-interference are used to reduce the coupling between transmit and receive chain.
  • a secondary (corrective) signal is constructed using the primary transmit signal and instantaneous
  • the antenna used to transmit the corrective signal can be a fully functional transmit antenna (similar to the other antenna used in the transmission) in the sense that it is connected to a power amplifier and has a low coupling with the corresponding receive antenna.
  • An alternative is to use an antenna which is designed exclusively for the purpose of self-interference cancellation and consequently has a high coupling to the receive antenna and can transmit with a low power.
  • a different approach is based on subtracting such a corrective signal in the receive chain prior to A/D using methods for RF signal combing, and in particular an RF coupler, which is an operation readily performed in the transmit chain of conventional radio systems.
  • the cancellation in analog domain due to the corrective signal is performed prior to Low-Noise-Amplifier (LNA). In another aspect, this is done after the LNA, and before the A/D.
  • Cancellation of self-interference stage can be further enhanced by a subsequent digital cancellation at the receive base-band. Generalization to MIMO will be clear to those skilled in the area. Regardless of which of the above methods for active cancelation are used, the corresponding weights may be referred to as the self-cancellation beam-forming coefficients.
  • apparatuses and methods include embodiments for cascading multiple analog cancellation stages as explained above, equipped with a disclosed training procedure.
  • a full-duplex link may be useful to provide security enhancement.
  • wireless radios are considered to be inherently insecure as the signal transmitted by any given unit can be freely heard by eavesdropper(s). This issue is due to the broadcast nature of wireless transmission. On the contrary, the same broadcast nature of wireless systems can contribute to enhancing security if nodes utilize full-duplex links. In this case, eavesdroppers hear the combination of the two signals transmitted by the two parties involved in a connection. In the language of Information Theory, this means eavesdropper sees a multiple access channel, and consequently faces a more challenging situation in decoding and extracting useful information.
  • Wireless nodes usually rely on sending a periodic preamble to initiate the link. This periodicity is exploited by a receiving end to establish time/frequency synchronization.
  • both nodes involved in a point- to-point two-way transmission can simultaneously send such a periodic preamble, which in turn, due to the linearity of the underlying channels, results in a combined periodic signal at an eavesdropper.
  • legitimate units may intentionally introduce a randomly varying offset in their frequency, which can be tracked by their intended receiver while making eavesdropping more difficult.
  • Methods of the key agreement protocols described herein, and devices configured to implement them utilize the ability to change the transmission channel. This can be achieved by changing the propagation environment around transmit and/or received antennas, for example though changing the reflections of the Radio Frequency (RF) signal from near-by objects, or changing other RF characteristics of the environment with particular emphasis on varying the phase, and/or polarization.
  • RF Radio Frequency
  • the methods described herein create multiple (preferably) independent options for the underlying multi-path channel. This is significantly easier as compared to traditional antenna beam-forming as in a rich scattering environment, a small perturbation in the channel interacts with many reflections from the surrounding environment and thereby results in a significant change.
  • a transmission channel in a rich scattering environment has many stable states (depending on the details of the propagation environment) and the system jumps from one such stable state to a totally different one with slightest change in the propagation environment.
  • M reflectors that could be individually turned on/off (i.e.,
  • mirror/transparent states we could create in total 2 M possibilities for the channel (could be specified by an -bit index and capable of carrying bits of data in media-based setup).
  • This mirror/transparent states can be realized using plasmas, inducing charge in semi-conductors, or mechanical movements, e.g., using Micro-Electro-Mechanical systems (MEMS).
  • MEMS Micro-Electro-Mechanical systems
  • phase is defined relative to some preamble, which is extracted locally at each unit. Full-duplex makes it possible to establish a global reference of phase between legitimate units.
  • the two legitimate parties communicate one phase value using the wireless channel that is between them (no public channel required), and then they will locally change the channel. It is relatively easy to change the channel phase, because small perturbations in the rich scattering environment will result in a new phase value of received RF signal for all parties, including for the eavesdropper. This process continues until Alice and Bob have enough number of such keys, and subsequently the channels are not changed any longer, and the extracted phase values are used to encrypt the message with PSK modulation. In case there are errors between these two keys, the channel code on top of the message symbols will correct it.
  • Alice 118 and Bob 102 each have two antennas (126, 124, and 104, 106, respectively) with very low coupling between the two antennas, using the methods described herein based on cascading multiple stages of analog cancellation.
  • Alice and Bob Prior to exchanging a phase value to be used as a key, Alice and Bob, the first the two legitimate parties, measure the filter coefficient to be used in multi-stage analog cancellation. This measurement is performed by sending a low power pilot such that any eavesdropper does not hear it. [0076] Then, one of the two legitimate parties acts master and the other one as slave.
  • her full-duplex transceiver 118 For example, if Alice is the master, her full-duplex transceiver 118 generates a sinusoidal signal of a known frequency and transmits it via channel 114 to Bob.
  • Bob the slave, forwards it from his receiver to his transmitter as shown by path 126, and amplifies it and forwards the received back to Alice via transmission channel 112.
  • Each unit operates in full-duplex mode to cancel their respective self-interference signals (116, 103) caused by the transmissions.
  • Both units may use continuous filtering in time to mitigate the delay problem associated with looping back the received signal back to the originating master. Note that the initial channel measurements can be still performed in OFDM domain, with filter structure translated into time domain implementations.
  • each unit accounts for its internal phase shift associated with its internal processing 126, 128 by accounting for its value and use the resulting phase as a PSK mask. That, while providing the loopback signal, each node may determine its own internal delay, or may even impose a pseudo random delay that is not known to the distant end master. When the units receive the masked signal from the distant end, they may first remove that pseudo random value, leaving only the common channel phase, which will be the same for each end. In this way, both transceivers 102, 118 are able to measure and obtain the same total channel round trip phase value.
  • either one of the transceivers, or both of them, may then alter their transmit antenna characteristics and initiate another phase measurement, taking turns as master and slave to mutually measure a round trip phase value.
  • one of the units may be configured to convey data using the sequence of shared-secret round-trip phase values.
  • the system may be configured to generate a random key such as a random binary sequence, apply FEC to the key value, and then PSK modulate the coded bits.
  • the resulting PSK symbols may then be masked with the sequence of phase values (accounting for its internal phase shift) and transmits them to the other party.
  • the recipient accounts for its internal phase shift (by subtracting it), then removes the mask by subtracting its estimate of the sequence of phase values, and finally demodulates the PSK symbols and decodes the FEC.
  • each of eavesdropper's antennas will hear two signals, but these signals are received through a channel of an unknown phase. Due to the fact that when phase values are added module 2 ⁇ , the result conveys zero information about each of them, eavesdropper will not be able to extract any useful information about the phase value exchanged between Alice and Bob.
  • the interference signals are generally referred to as 108, 110, 120, 122, but in reality, each transmit 104, 124 has a unique channel to each of the eavesdroppers 124 antennas.
  • FIG. 4 shows an alternative message transmission and loopback associated with the second measurement of the common phase once the role of master and slave is reversed, where Bob initiates the transmission.
  • each transceiver reversed the roles of its antennas, and instead of transmitting with antenna 104, transceiver 102 initiates its transmission with antenna 106, which is the antenna that it had previously used to receive the signals from Alice during the prior first phase measurement.
  • Alice receives the signal on antenna 124 and retransmits the loopback signal using antenna 126.
  • antenna structures are connected to both transmit and receive chains (transmit in one interval and receive in another one). This feature enables a reliance on the reciprocity of the channel, and thereby reduces the total number of transmissions between Alice and Bob such that an eavesdropper is not able to gather enough equations to solve for the unknowns. Consequently, eavesdropper 124 cannot obtain useful information about the exchanged phase value.
  • the disadvantage of this setup is that each antenna should be connected to both transmit and receive chains, but in return, it is robust with respect to any remaining amount of self-interference.
  • Alice and Bob measure their loop-back interference channels from Bob/TXl to Bob/RX2 and from Alice/TX2 to Alice/RXl (send low power pilots after scrambling and loop back in each unit).
  • Alice/TXl sends pilots (after scrambling) to Bob/RX2, who (using Bob/TXl) forwards it to Alice/RX2.
  • Bob/TX2 sends pilots (after scrambling) to Alice/RXl , who (using Alice/TX2) forwards it to Bob/RXl .
  • the two units knowing their loop-back channels and relying on reciprocity, compute the channel: (Alice/TXl- Bob/RX2) x (Bob-loop-back) x
  • FIG. 6 shows that in the second method for key exchange, eavesdropper in total listens to four transmissions, but also adds four unknowns (e.g. channel phase to their receive antenna(s)) and consequently cannot extract any useful information from such measurements.
  • unknowns e.g. channel phase to their receive antenna(s)
  • legitimate units locally impose stricter requirements on the level of self-interference cancellation at their respective units. For example, this can be achieved if each node locally examines multiple channel perturbations and select those one that result in the lowest amounts of self-interference. This in return enables a relaxation of the requirement of each antenna being connected to both transmit and receive chains.
  • the input and output signals (/,, O I 2 , 0 2 ) of Alice and Bob in baseband form a four-dimensional vector that spans a two-dimensional sub-space (two equations are dictated by the overall structure). For linear systems: 1 G 21
  • two pilots are transmitted simultaneously, which can be considered as unit vectors, from Alice and Bob. Then, in the next transmission, one of them, say Bob, sends the negative of the same pilot.
  • These two steps provide enough equations to Alice and Bob to compute two common phase values corresponding to the transmitted pilots times their corresponding channel gains. For better security, only one of these (or a function of the two) is used as the key.
  • the environment (channels) at the neighborhood of both Alice's and Bob's transmit antenna(s) are perturbed, possibly with local selection among multiple perturbations to reduce the amount of self-interference. Then, Bob and Alice send low power and scrambled pilots to measure their self-interference channels to be used towards cancellation of self-interference and the process continues to obtain another common phase value.
  • Full-duplex links also provide a means to enhance information theoretical security. It should be added that information-theoretical security has its own challenges in term of
  • eavesdropper Eve receives the sum of Alice's and Bob's signals which would make eavesdropping more difficult.
  • eavesdropper Eve receives the sum of Alice's and Bob's signals which would make eavesdropping more difficult.
  • One extreme option of maximizing the rate form Alice to Bob is that Bob transmits a secret key to be used by Alice, as a complete key or as a partial key, in its next block transmission.
  • an embodiment relies on the following principle.
  • a periodic preamble for the purpose of frequency synchronization between transmitter and receiver. This frequency synchronization is important because the slightest mismatch in frequency will make it significantly more difficult for the receiver to detect the signal.
  • Alice starts sending a periodic sequence to Bob, and Bob also sends a similar periodic sequence with high power.
  • An eavesdropper will receive the sum of these periodic sequences passed through their respective channels and the received signal remains periodic. In each transmission, say each OFDM symbol, Alice
  • the ability to change the channel from symbol to symbol is used in the key generation protocols. This is achieved by changing the RF environment around transmit antenna(s).
  • beam-forming using tunable RF usually based on changing the dielectric or conductivity property by applying voltage, is an active area of research. Note that for the specific scenarios of interest, the channel may be changed from one random state to another random state. This means, unlike the case of beam- forming, it is not necessary to know what the current state is and what the next state will be, there is no intension to control the details of the channel state either, and any variation in channel phase will be sufficient to satisfy the needs.
  • the intension is usually to focus the energy in a directional beam, and preferably to be able to steer the energy beam. Due to natural inertia that exists, it is usually more difficult to modify the energy density, rather than just changing the phase. Particularly, in the case of rich scattering environments, it is relatively easy to change the channel phase, to move from one stable point to a totally different point with independent values.
  • an RF-mirror is defined as an object, which would pass, reflect, partially pass/partially reflect an RF signal.
  • An RF-mirror can have static parts with fixed RF properties, as well as dynamic parts with RF proprieties that are dynamically adjusted through digital (on- off) or analog control signals. Such a constriction will be called a tunable RF-mirror hereafter.
  • RF-mirrors and tunable RF-mirrors will be useful components in inducing channel variations.
  • FIG. 9 shows an example for the realization of an RF-mirror.
  • Material releasing electrons or holes referred to as a charge-releasing-object hereafter, releases charge, typically electrons, in response to the energy absorbed from a source of energy, typically a laser, which in turn reacts to the control signals.
  • charge-releasing-object to be used with a light source is a semi-conductor, e.g., structures used in solar cells, Gallium Arsenide, materials used as photo-detectors in imaging applications such as a Charge-Coupled-Device (CCD), materials used to detect light in free space optics, materials used to detect light in fiber, or high resistivity silicon, typically with a band-gap adjusted according to the light wave-length.
  • CCD Charge-Coupled-Device
  • Another example is plasmas with their relevant excitation signaling as the energy source.
  • the intensity of light which is typically controlled by the level of input current to the laser and number of lasers that are turned on, contributes to the amount of light energy converted into free electrons and consequently affects the conductivity of the surface.
  • This feature can be used to convert the corresponding RF-mirror to a tunable RF-mirror.
  • a mirror to reflect light called a light-mirror hereafter, on top to increase contact of the light with the surface of the charge-releasing-object underneath, and even adjust such a light-mirror towards tuning of the overall RF-mirror.
  • FIG. 10 shows a second example 1000 where a light-mirror 1006 is placed around the charge-releasing-object.
  • the objective for this light-mirror is to confine the light to increase the amount of energy absorbed by the charge-releasing-object.
  • This feature can be further enhanced by creating cuts in the light-mirror to stop reflections for any given light source at a point of interest. These cuts can be controllable as well (pieces of on-off light-mirrors) to enhance the controllability of the amount of released charges and thereby the behavior of the RF- mirror in response to the RF signal.
  • Light source 1004 such as a laser runs through or on the surface of the material.
  • the circular, or polygon, region 1006 with material reflecting light except for the places shown as cuts 1008 (referred to as a light mirror).
  • the device 1020 of FIG. 10 shows a closer look at the example for the light-mirror around the charge-releasing-object 1030.
  • the light from each laser 1022, 1026, and 1028 depending on its angle, can go through many reflections at distinct points, covering several turns around the loop, until it hits the mirror at one point for the second time. This completes one cycle of reflection as shown by path 1032. After this second incidence, the same path will be covered again and again with subsequent cycle overlapping in space.
  • the starting angle of the beam light the number of such reflections in a cycle can be adjusted which in turn affects the area of the charge-releasing-object that is exposed to light.
  • This feature can be used to have a tunable RF-mirror (depending on the combination of light sources that are turned on), even if all sources have a constant power. Additionally, it is possible to adjust the level of input current driving the laser(s) for tuning purposes. Note that path 1024 is such that the angle of the laser and positions of the cuts are such that the beam from source 1028 ends by exiting through the cut prior to completing a cycle.
  • FIG. 11 shows a different approach to create an RF mirror.
  • the switches on any one surface will be either all closed, or all open, which results in an on-off RF mirror.
  • FIG. 12 illustrates methods to surround a transmit or receive antenna with objects capable of RF perturbation, e.g., on-off RF mirror, including methods to enhance the inducted channel variations. [0098] Next, some additional methods of using "induced channel variations" are explained.
  • Methods explained herein use the induced channel variations to increase a number of extracted common phase values. Once this capability is present, it can serve some other objectives as well, e.g., reducing transmit energy for a given transmit rate and coverage, or a combination of these two objectives. Examples include increasing diversity to combat fading; increasing error correction capability to combat multi-user interference or other factors degrading transmission; and avoiding poor channels in terms channel impulse response.
  • the objective for example, can be to improve Signal-to-Interference-Ratio (SINR) including the effect of multi-user interference, enhance diversity in OFDM domain, or improve link security in key exchange.
  • SINR Signal-to-Interference-Ratio
  • Methods herein may use the observation that the channel impulse response affects the structure of the receiver match filter, and thereby affects the level of multi-user interference at the base-band of the desired receiver. If the purpose is enhancing diversity, channel can be varied between OFDM symbols (kept the same during each OFDM symbol).
  • receiver needs to learn the OFDM channel for each OFDM symbol. This can be achieved through inserting pilots in each OFDM symbol and/or through inserting training symbols. In the latter case several OFDM symbols can be grouped together to reduce training overhead, i.e., each group of OFDM symbols relies on the same training and channel is varied between such groups. Furthermore, pilots can be inserted among OFDM tones to facilitate training, fine-tuning and tracking.
  • Another method to exploit induced channel variation is to use the feedback link, e.g., the one present in two-way links, to select the channel configuration with a preferred impulse response towards increasing received signal energy as well as reducing interference.
  • the details of the impulse response affects the receiver structure, which normally relies on a matched receiver.
  • the impulse response from a node T to a node R affects both the gain from T to R as well as the amount of interference at R from an interfering transmitter, say T'.
  • Conventional methods usually rely on multiple antennas and antenna selection to improve received signal strength and reduce received multi-user interference.
  • antenna selection at the transmitter T only affects the forward gain from T to R and does not have any impact on the interference from T' on R.
  • conventional methods require antenna selection to be performed at R and this results in some limitations.
  • These conventional methods need a separate antenna to provide additional independent gain values over the links connected (starting from or ending to) to that antenna.
  • Methods of this disclosure realize similar advantages while avoiding some of the disadvantages associated with these earlier approaches.
  • One advantage is that it is fairly easy to induce channel variations resulting in different impulse responses. For example, by relying on Q on-off RF -mirrors, methods of some embodiments of this disclosure can create 2 Q different impulse responses. This feature makes it possible to increase the number of candidates available for the selection at an affordable cost. Methods of this disclosure also benefit from the
  • transmitter T in communicating to R also affects the interference received at R from an interfering transmitter node T' (selection is based on considering both signal and interference).
  • selection is based on considering both signal and interference.
  • selecting a different antenna at the transmitter side T does not affect the level of interference from T' on R.
  • methods of this disclosure based on channel impulse selection and matched filtering (to improve signal and reduce interference) are still applicable as these involve processing in time prior to taking the received signal to frequency domain.
  • an additional criterion for channel impulse selection can be based on the level of frequency selectivity in the resulting OFDM channel to increase diversity in the frequency domain.
  • some embodiments also include methods in which static objects (called parasitic elements hereafter) that can affect the propagation properties, e.g., pieces of metal to reflect RF signal, are placed in the vicinity of the transmit and/or receive antenna(s) to enhance the induced channel variations.
  • the length of the impulse response also plays a role in separating signals and exploiting advantages offered by the induced channel variations.
  • Placement of parasitic elements affects the length of the channel impulse response. In particular, to enhance frequency selectivity, a longer channel impulse response is needed. To realize this, methods of some embodiments include placing parasitic elements in the form of reflectors;
  • FIG. 10 shows a pictorial view (viewed from top) for an example of such a chamber.
  • Walls of the chamber can be, for example, construed using constructions disclosed in FIGs. 9 and 10.
  • the size of walls and placement of openings for the chamber can be static or dynamically tuned to adjust the channel impulse response. Openings may include air and/or delay elements formed from materials with proper (preferably tunable) conductivity, proper (preferably tunable) permittivity, or proper (preferably tunable) permeability.
  • Example for tunable conductivity include: 1) Injecting electron into a semi-conductor, e.g., using a metal-semiconductor junction, 2) Freeing electrons in semiconductors, e.g., through light, laser or heath, and 3) Ionizing (plasma).
  • Tunable permittivity can be realized using ferroelectric materials (tuned using an electric field/voltage).
  • Tunable permeability can be realized using ferromagnetic materials (tuned using a magnetic field/current).
  • Another design disclosed herein concerns the use of RF MEMS to adjust the position and angle of the energy sources, typically lasers, in the tunable RF mirror to adjust the impulse response, or create effects similar to an RF dish to guide the RF signal in far field, e.g., for the purpose of beam-forming.
  • Another aspect of some disclosures involves stacking several such tunable RF mirrors in parallel to provide more flexibility in realizing a desired RF channel characteristic.
  • such a construction can be used to provide the effect of an RF dish by adjusting the energy source, typically lasers, to end their cycle such that different layers in the stacked structure act as reflectors contributing to steering the RF signal in a desired direction.
  • a laser beam will become conductive and acts as a parasitic antenna elements and knowledge developed in the context of RF beam forming using parasitic elements will be applicable.
  • Another design disclosed herein concerns modulating the energy source, typically laser beams, to expand their spectrum to cover a high range of frequencies. This feature helps in using the energy source with a small frequency range to the wider frequency range of the charge-releasing-object. For example, the laser's original frequency range, i.e., if excited to be always on, may be too narrow with respect to the frequency range of the charge-releasing- object, and this limits the amount of absorbed energy. Typically, a charge-releasing-object has a wider frequency range, even if it is designed to match a particular laser.
  • such a modulation can be simply a periodic switching of the laser (i.e., using a rectangular pulse train to excite the laser), or using some other time signals for switching.
  • Another complementary option is to use several lasers, each covering part of the frequency range of the charge-releasing-object.
  • Anti-Refection (AR) coating of parts relevant to both RF frequencies and light frequencies can be useful addition(s) to this design.
  • Walls of the chamber trap the RF signal and cause a varying number of reflections and delays for different parts of the RF signal before these get into the air for actual transmission (on the transmit side), or before actual reception after arriving from the air (on the receive side).
  • this construction acts as a wave-guide and consequently can rely on structures known in the context of wave-guides to cause or enhance effects required in the methods disclosed herein for inducing channel variations.
  • Such walls can be combination of static elements and some that are dynamically adjusted (tuned) at speeds required to adapt the channel impulse response (this is typically much less than the rate of signaling).
  • Walls may have openings or be composed of pieces with different conductivity and/or permittivity and/or permeability to let some of the trapped wave to exit the chamber after delay and phase/amplitude changes caused by traveling within the chamber.
  • control signaling can affect the propagation environment in small increments.
  • this disclosure includes methods to form a closed loop between a transmitter and its respective receiver wherein the control signals (affecting the channel impulse response) are adjusted relying on closed loop feedback, e.g., using methods known in the context of adaptive signal processing.
  • the criterion in such adaptive algorithms can be maximizing desired signal, and/or minimizing interference, and/or increasing frequency selectivity for diversity purposes.
  • stability may be compromised due to three closed loops.
  • aspects of this disclosure relate to the design of a full-duplex radio.
  • a full-duplex radio has separate antennas for transmission and reception.
  • the transmit and receive antennas may often be placed in the vicinity of each other and consequently a strong self- interference may be observed at the receive antenna.
  • the description herein illustrates systems and methods for practical implementation of full-duplex wireless using a primary transmit signal and auxiliary transmit signal to reduce interference, and a residual self-interference cancellation signal. To this aim, new self-interference cancellation techniques are deployed.
  • a method of full-duplex communication may comprise: in a full duplex transceiver, generating an interference-reduced signal by combining an analog self- interference cancellation signal to an incoming signal that includes a desired signal and a self- interference signal, wherein the analog self-interference cancellation signal destructively adds to the self-interference signal to create a residual self-interference signal. Then, the method may include further processing the interference-reduced signal to further reduce the residual self- interference signal using a baseband residual self-interference channel estimate.
  • the method may comprise: determining an estimate of a self- interference channel response from a primary transmitter of a transceiver to a receiver of the transceiver and determining an estimate of an auxiliary channel response from an auxiliary transmitter of the transceiver to the receiver. Then, the method may include determining a residual self-interference baseband channel response at a baseband processor of the receiver. Full-duplex communication is performed by preprocessing a primary transmit signal and an auxiliary transmit signal with the estimated auxiliary channel response and a negative of the estimated self-interference channel response, respectively, and transmitting the preprocessed primary transmit signal and the preprocessed auxiliary transmit signal in a transmit frequency range, while receiving a desired signal within a receive frequency range substantially
  • the method may reduce the residual self-interference signal using the residual self- interference baseband channel response; and, further processing the desired signal.
  • an apparatus may comprise: a weight calculation unit configured to measure a self-interference channel and an auxiliary channel to obtain an estimate of the self-interference channel and an estimate of the auxiliary channel; a full-duplex transceiver having a primary transmitter, an auxiliary transmitter, and a receiver, wherein the primary transmitter and auxiliary transmitter are configured to preprocess a training sequence to generate two transmit signals such that the two transmit signals respectively traverse the self-interference channel and the auxiliary channel and combine to form an analog residual interference signal at the receiver of the full-duplex transceiver; an analog to digital converter and a receiver baseband processor at the receiver being configured to measure a baseband residual self-interference channel response by; and, the transceiver being further configured to cancel self-interference signals using the auxiliary channel and to cancel residual self-interference signals using the measured baseband residual self-interference channel response.
  • the full-duplex transceiver may communicate in full-duplex by transmitting information in a first frequency band to a second receiver while simultaneously receiving information in the first frequency band from a second transmitter by cancelling self-interference signals using the auxiliary channel and cancelling residual self-interference signals using the measured baseband residual self- interference channel response.
  • antenna design is employed to reduce the incidence of self-interference 402 at a full-duplex communication node 400.
  • Symmetrical (e.g., pair-wise, triple-wise) transmit and receive antennas are relatively positioned to reduce coupling between transmit and receive and thus reduce the incidence of self-interference.
  • access points and clients of the communication network are configured to reduce self-interference between a component's own respective antennas and transmit and receive chains.
  • various embodiments include a second class of antenna pairs with low, but non-zero coupling. This is based on placing one set of antennas in the plane of symmetry of another set. In 3-dimensions, it is shown there exist triple-wise symmetrical antennas with zero coupling between any pair. It is also shown that in 3-dimensions, one can indeed find two sets of antennas (to be used for transmit and receive in a MIMO system) such that any antenna in one set is decoupled (zero coupling over the entire frequency range) from all the antennas in the second set.
  • Such three dimensional structures are generalized to the case that antenna arms are placed closely or merged, for example using two-sides or different layers of a PCB, or analogous approaches based on using Integrated Circuit (IC).
  • An example for the implementation of such constructions is based on using patch antennas wherein one antenna arm is generated through reflection of the other antenna arm in the ground plane. Examples of such a construction are presented wherein the same patch is used as the transmit antenna, the receive antenna and the coupler necessary in analog cancellation. Examples are presented to generalize such constructions for MIMO transmission. Hereafter, such constructions are referred to as being in 2.5 dimensions, or simply 2.5 dimensional.
  • OFDMA Orthogonal frequency division multiple Access
  • DS Direct Sequence
  • TDMA Time-division Multiple Access
  • SDMA Space Division Multiple Access
  • a corrective self-interference signal 404 is generated and injected into the receive signal at 412. Weighting coefficients for filtering are calculated for a primary transmit signal and an auxiliary transmit signal comprising the corrective self- interference signal 404.
  • the corrective self-interference signal may be transmitted by the node to combine in the air with the signal to be received by the node's receive antenna. Transmission of the corrective self-interference signal can be at power levels comparable with the primary signal using an antenna with comparable functionality as the antenna used to transmit the primary signal. This can be the case if multiple high power transmit antennas are available in the unit.
  • an auxiliary transmit antenna with high coupling to the receive antenna, may be used to transmit the corrective self-interference signal with low power.
  • the corrective self- interference signal may be coupled (e.g., in RF in the receive chain of the node without the use of an antenna) to the signal received by the receive antenna.
  • the analog cancellation may take place at an RF coupler 418, or alternatively it may take place at baseband frequencies using circuit 420.
  • another technique for cancelling self-interference is to determine the response of a transmit- to-receive baseband channel, also referred to herein as a residual interference channel, or a residual self-interference baseband channel.
  • the baseband version or frequency domain version of the transmit signal 408 may be provided to the receiver baseband processor 414 for a further analog subtraction 414 by processing the transmit signal with the residual self-interference response and then subtracting it from the incoming signal to obtain the received signal 416 prior to A/D conversion.
  • FIG. 14 one embodiment of a full-duplex transceiver is shown.
  • OSDN data 512 is provided to the transmitter baseband processor 510.
  • This signal will form the basis of the primary transmit signal 526 that is propagated between the transmit antenna and receive antenna with low coupling as described herein.
  • the baseband processor 510 generates OFDM symbols for transmission and passes them to preprocessor unit 508.
  • Preprocessor unit 508 multiplies the OFDM symbols by the transfer function H 2 , which represents the transmission channel of the auxiliary transmit path 534.
  • the signal is then converted to a time domain signal and passed through digital to analog converter 506.
  • transmit baseband processor 510 generates the time domain signal with an IFFT module and preprocessing filter 508 is implemented in the time domain, such as by an FIR filter.
  • the output of preprocessing unit 508 is converted to an RF signal by modulator 504, and amplified by power amplifier 502, and finally transmitted to a distant end receiver (not shown).
  • the OFDM data 524 is provided to the auxiliary transmit baseband processor 522. Similar to the primary transmit chain, the auxiliary
  • preprocessor 520 may alter the OFDM symbols by an estimate of the transfer function (- H , which is the negative of the channel response of the interference channel 536.
  • the output of the auxiliary transmit baseband processor 522 may be time domain signals calculated by an IFFT module, and the preprocessor unit 520 may be an FIR filter to process signals in the time domain.
  • the output of preprocessor 520 is provided to a digital to analog converter 518, and then to RF modulator 516, to generate the auxiliary transmit signal 514, also referred to as the self-interference cancellation signal.
  • the self-interfering signal 526 combines with the self- interference cancellation signal 514 by way of RF addition 528.
  • the self interference is cancelled by determining the characteristics, or frequency response, of (i) the self-interference channel ⁇ caused by the primary transmit signal as coupled through the primary transmit antenna and the receive antenna, and (ii) the self-interference cancellation channel H 2 caused by the auxiliary transmit path, which conveys the self interference cancellation signal.
  • the channel responses may be determined by channel sounding techniques, including transmitting predetermined tones and measuring the magnitude and phase variations of the tones in the received signal.
  • the channel responses ⁇ and H 2 are the responses of the complete channel from the OFDM data at the respective transmitters through their respective chains, through the analog signal propagation/ RF channels, the receiver analog front end, all the way to the receiver baseband 538.
  • the self-interference signal 526 is substantially reduced by the negative contribution of the self-interference cancellation signal 514, by way of RF addition 528.
  • the remaining received signal is then demodulated by RF demodulator 530, and is sampled by analog-to-digital converter 532.
  • the sampled signal is then processed by receive baseband processor 538/540.
  • Receive baseband processor 538/540 performs an FFT to generate the OFDM symbols 542.
  • both preprocessors 602, 604 may apply the channel responses by operating directly on the OFDM transmit signals by altering the magnitude and phase of the symbols according to the channel response. Alternatively, the preprocessing may be performed in the time domain.
  • the self-interference channel ⁇ and the self- interference cancellation channel H 2 as determined by the full-duplex transceiver are only estimates of the actual channel responses and may include errors ⁇ 1 and ⁇ 2 , respectively, as shown in preprocessing units 508, 520.
  • a residual interference signal remains after the RF addition.
  • This residual signal is separately measured at the receiver baseband processor, as described more fully below, and is referred to herein as the residual self- interference baseband channel response.
  • both preprocessors may apply the channel responses by operating directly on the OFDM transmit signals by altering the magnitude and phase of the symbols according to the channel response. Alternatively, the preprocessing may be performed in the time domain.
  • FIG. 15 shows a further alternative embodiment where the residual error channel is measured and is then cancelled using a second auxiliary transmit channel for cancellation in the analog domain. This allows the residual error signal to be removed in in the time domain without having to go through an OFDM symbol time.
  • FIGs. 16 and 17 show block diagrams representing transmit and receive chains, in accordance with examples of embodiments of the full-duplex transceivers. These embodiments differ in the method used to construct the axillary corrective signal from the main transmit signal and the method used to couple (add) the corrective signal with the incoming signal.
  • the cancellation in analog domain due to the corrective signal is performed prior to Low-Noise- Amplifier (LNA). In another embodiment, this is done after the LNA, and before the A/D.
  • the filtering is performed in time domain. In another
  • filtering is performed in the frequency domain. In some embodiments
  • the construction of a secondary (corrective) signal uses the data from the primary transmit signal and an instantaneous measurement of the self-interference channel.
  • the corrective signal, or self-interference cancellation signal is subtracted (in the analog domain) from the incoming signal prior to A/D. This can be achieved by using multiple, in particular two, transmit antennas with proper beam-forming weights such that their signals are subtracted in the air at the receive antenna.
  • the antenna used to transmit the corrective signal can be a fully functional transmit antenna (similar to the other antenna used in the transmission) in the sense that it is connected to a power amplifier and has a low coupling with the corresponding receive antenna.
  • This scenario may be of interest if there are several transmit units available which can be used in different roles depending on the mode of operation.
  • An alternative is to use an antenna that is designed exclusively for the purpose of self-interference cancellation and consequently has a high coupling to the receive antenna and can transmit with a low power.
  • a different approach is based on subtracting such a corrective signal in the receive chain prior to A/D using methods for RF signal coupling. Regardless of which of the above methods for active cancelation are used, the corresponding weights may be referred to as the self-cancellation beam-forming coefficients. To improve mathematical precision by avoiding dividing of numbers, it helps if the weighting is applied to both primary and secondary, while scaling both to adjust transmit energy. However, an equivalent filtering operation can be applied to only one chain, in particular to the auxiliary corrective signal. Aspects of filtering for construction of the auxiliary corrective signal are mainly explained using frequency domain realization, however, filtering can be also performed in the time domain.
  • channel impulse responses are measured in the frequency domain, and then converted to a time-domain impulse response or difference equation used to implement the filter in the time domain.
  • Time domain filters may act continually on the signal in the time domain, or account for and compensate for the initial condition due to the filter memory from the previous OFDM symbol.
  • FIG. 16 shows one embodiment of a full-duplex transceiver 800.
  • the transmit data 816 is provided to transmit baseband 814 of primary transmit chain 804, which formulates OFDM symbols and forwards them to IFFT processing unit 812 for conversion to a time domain signal.
  • the data is then converted to an analog signal by digital to analog converter 810.
  • the analog signal is then modulated by RF modulator 808, and amplified by power amplifier 806.
  • the signal is then transmitted to a distant end receiver (not shown), and the transmission causes a self interfering signal 802 to be received by the receive chain 832.
  • the transmit data 816 is also provided to auxiliary transmitter 820, where the baseband processor 830 generates OFDM symbols.
  • the OFDM symbols are converted to a time domain signal by IFFT processor 828, and then converted to a time domain signal by digital to analog converter 826.
  • the auxiliary transmit signal is then modulated by RF modulator 824, and amplified by amplifier 822 for transmission to the receiver chain 832 via path 818.
  • the preprocessing of the primary transmit signal and the auxiliary transmit signal may be performed by transmit baseband processor 814 and auxiliary transmit baseband processor 830, respectively.
  • the TX base-band component 814 and ATX base-band component 830 receive weights from weights calculation unit 846 to perform the corrective beam forming (when transmitted for combining in the air) or signal injection (i.e. when added in RF on the unit 800).
  • the amplified signal from amplifier 804 is transmitted, via a pair- wise symmetrical transmit antenna whereas the amplified signal from amplifier 820 is output for combining with a received signal from a pair- wise symmetrical receive antenna of receiver 832 via RF coupling unit 834.
  • a low noise amplifier 836 amplifies the combined received and injected signal.
  • the amplified signal is demodulated (by
  • demodulator 8348 and analog to digital conversion is performed at A/D Unit 840.
  • the digital signal is passed to FFT unit 842 and thereafter to RX base-band 844, which provides received data 848 and information (measurements) to weights calculation unit 846.
  • Remaining degradations in receive signal can be further reduced by forming an appropriate digital or analog corrective signal and applying it in the base-band (or IF), or even via RF transmission according to FIG. 15. This may be an attractive option to account for the degradations that are caused by non-linear operations such as rounding, lack of precision in FFT/IFFT etc.
  • TRBC Transmit-to-Receive Base-band Channel
  • a method may comprise full duplex nodes represented as Alice and Bob configured to reduce the amount of self-interference and each node performing respective operations to exchange a key comprising:
  • Channel values for canceling self-interference are measured (quietly by transmitting low power and possibly scrambled pilots) in each node: 2. Each unit transmits the sum of its received signal and its input signal.
  • Alice/Bob simultaneously sends pilots A/B, followed by -A/B, respectively;
  • Each node obtains two equations which are used to find phase values of AG 12 and BG 21 where Gn and G 21 are the cross gains between Alice and Bob; and,
  • Channels are perturbed (at both nodes) to change the channel phase prior to a next round to determine a further key.
  • the nodes are full duplex nodes represented as Alice and Bob, each node performing respective operations to enhance security comprising:
  • the RF channel is perturbed relying on methods known in the context of RF beam- forming said methods selected from one or more of: using meta- materials, absorber/reflector surfaces, Ferroelectric materials, changing conductivity of semiconductors by applying voltage or other forms of energy including light, electronically controlled antennas e.g., by changing impendence through switching of conducting pieces of metals, optically controlled antennas, ferrite-type dielectric antennas, and plasma antennas.
  • the RF channel is perturbed by surrounding the antennas with walls composed of plates that have a conductive surface which is transparent to RF signal at the carrier frequency of interest, e.g., by using periodic structures, and each wall has two such plates filled with a dielectric in between, with both of the two plates separated from the dielectric material using a layer of non-conducing material, and where the RF property of the dielectric are changed by applying voltage across the two plates forming each wall.
  • Further methods may use a full duplex link to form a closed loop between a transmitter and its respective receiver wherein the control signals (affecting the channel impulse response) are adjusted relying on closed loop feedback, e.g., using methods known in the context of adaptive signal processing.
  • Still further embodiments include a wireless communication node configured to perform a method according to the foregoing disclosure.
  • FIGs. 20-23 show pictorial views of pair- wise symmetrical antennas for components in accordance with examples.
  • the plane of symmetry for the vertical antenna 2002 is the plane passing through the x axis, and the plane of symmetry for the horizontal antenna 2004 passes through the y axis.
  • the dots such as dot 2000 indicate terminals, and that radiating elements 2002 and 2004 are "V" shaped to illustrate the use of physical symmetry, and are not intended to represent actual radiating element geometries.
  • FIG. 22 shows a 3- dimensional arrangement where the horizontal antenna has its terminals in the XZ plane near the Z axis, with its plane of symmetry being the YZ plane.
  • the vertical antenna has its terminals in the YZ plane, also close to the Z axis but closer to the origin, where the XZ plane is the plane of symmetry.
  • FIG. 23 shows antenna 2302 is a ring (in the XY plane).
  • each two antennas are pair-wise symmetrical, meaning there is theoretically zero coupling between any pair.
  • the 3x3 S -matrix is diagonal in theory, or close to diagonal in practice, independent of frequency.
  • FIGs. 26-28 show examples of MIMO antenna structures in 3-dimensional space where every antenna in one subset, is decoupled from all the antennas in the second subset, using pairwise symmetry.
  • FIG. 26 utilizes the third dimension to stack the parallel and horizontal antennas along the Z axis, while FIG. 27 staggers each of the horizontal antennas 2702 and the vertical antennas 2700 along the Z axis.
  • Multiple-Input Multiple-Output Antenna systems are based on using multiple antennas at each node and exploit the resulting spatial degrees of freedom to increase the rate and/or increase the diversity order.
  • For a MIMO full-duplex radio there is a set of TX antennas and a set of RX antennas.
  • each antenna in TX set may be pair- wise symmetrical with respect to all antennas in RX set and vice versa.
  • a straightforward approach is to use the symmetry planes of TX and RX antennas to generate more elements in each set, but this configuration results in unwanted distance between antenna arms and thereby affects their radiation efficiency.
  • antenna arms can be brought closer by placing antennas on different PCB layers or its equivalent in other forms of realizing antennas in integrated circuit, or multi-layer antennas with layers coupled through air or through other materials with desirable electromagnetic property that can guide or block the wave.
  • MIMO implementation in three dimensions is more flexible (easier to implement). This is due to the observation that a pair- wise symmetrical antenna structure requires two dimensions effectively, and as a result, it is possible to generate more
  • antennas satisfying the required symmetry condition along the third dimension.
  • Some example configurations are shown in FIGs. 26, 27, and 28 of MIMO antenna structures in 3-dimensional space where every antenna in one subset is decoupled from all the antennas in the second subset.
  • FIG. 29 shows examples for the placement of one antenna set in the plane of symmetry of some other antenna(s) to support MIMO in 2-dimensional antenna structures in accordance with one example. While the configuration does not contain pairwise symmetry, the four verticals are symmetrical and their associated electric field is orthogonal to plane of symmetry, and the horizontal antennas are in that plane of symmetry, thereby reducing the coupling because the E-field is orthogonal. This configuration of FIG. 29 may be used for MIMO.
  • FIGs. 30-32 show examples of some antenna structures showing that the coupling between antennas can be very strong (-2dB) due to near field signals unless it is cancelled relying on pair- wise symmetry where values of RF coupling are obtained using high frequency structural simulator (HFSS) at 2.4Ghz band.
  • HFSS high frequency structural simulator
  • FIGs. 33 and 34 show numerical results (2.4Ghz band using HFSS) for one example of modifying the shape of the antenna to compensate for the loss in symmetry. This demonstrates that the shape of the radiating elements may be adjusted so as to reduce the coupling.
  • FIGs. 35 and 36 show a schematic view of two pair- wise symmetrical antennas composed of a dipole and a patch antenna which has an arm above ground plane; and wherein diploe can be realized on the middle layer of a PCB sandwiched between the top and bottom surfaces forming the patch and the ground plane. This arrangement maintains pairwise symmetry.
  • the active antenna elements can be enclosed within a periodic structure that includes a substantially cylindrical array of independently switchable RF reflectors, such as the switchable RF reflector illustrated in FIG. 11. Switches on a given wall, can be all or partially switched to change the channel. Reflective walls reflect the wave from an active antenna element and form a cavity internally which results in several reflection for the RF signal prior to exiting the cylinder. This adds to the richness (independence) of the various channel configurations.
  • the substantially cylindrical array of switchable RF reflectors may also be surrounded by a set of exterior metallic strips acting as non-switchable radio-frequency reflectors.
  • the non-switchable radio-frequency reflectors may be arranged in a substantially cylindrical fashion around the switchable RF reflectors. Reflections between these exterior metallic strips further enrich the channel variations caused by switching the switchable RF reflectors.
  • an antenna assembly 3800 includes a first active antenna element 3802 and a second active antenna element 3804.
  • Active antenna elements 3802 and 3804 are pairwise symmetric with respect to one another to minimize self-interference when one element is used as a transmit antenna and the other is used simultaneously as a receive antenna.
  • Active antenna elements 3802 and 3804 may be, for example, dipole antennas.
  • a plurality of switchable radio-frequency reflectors, such as reflector 3806 is positioned in a substantially cylindrical array around the active antenna elements 3802 and 3804.
  • Each of the switchable radio-frequency reflectors, such as reflector 3806 includes a plurality of conductive segments connected by one or more switching components, such as PIN diodes.
  • the switchable radio-frequency reflectors include switchable plasma components, such as switchable plasma-filled tubes.
  • a plurality of non- switchable radio-frequency reflectors, such as reflector 3808, are positioned in a substantially cylindrical array around the switchable reflectors.
  • Non-switchable reflector 3808 may be, for example, a strip of metal.
  • An antenna assembly 3900 includes a first active antenna element 3902 and a plurality of switchable radio- frequency reflectors, such as switchable reflector 3904, that surround the first active antenna element 3902 in a substantially cylindrical array.
  • the first active antenna element 3902 may be a dipole antenna or other omnidirectional antenna.
  • the switchable radio -frequency reflectors may also be surrounded by a plurality of non-switchable radio-frequency reflectors, such as metal strip 3906.
  • the antenna assembly 3900 further includes a second active antenna element 3908. While the first set of switchable radio -frequency reflectors is positioned only around the first active antenna element 3902, a second plurality of switchable radio-frequency reflectors, such as switchable reflector 3910, surround the second active antenna element 3908 in a substantially cylindrical array.
  • the second active antenna element 3902 may be a dipole antenna.
  • the switchable radio-frequency reflectors may also be surrounded by a plurality of non-switchable radio-frequency reflectors, such as metal strip 3912.
  • the first active element 3902 and the second active element 3908 may be pairwise symmetric to minimize self-interference when one element is used as a transmit antenna and the other element is used as a receive antenna at the same time.
  • the separate active antenna elements of antenna assembly 3800 (FIG. 38) and antenna assembly 3900 (FIG. 39) may be connected to the separate transmit and receive circuitry (such as the TX and RX circuitry of FIG. 8) of a single transceiver.
  • the antenna assemblies 3800 or 3900 can be used as the transmit and receive antennas of the circuitry illustrated in FIG. 16.
  • the transmit chain 804 (FIG.
  • the transmit chain 804 may transmit through active antenna element 3902 while the receive chain 832 receives a signal from active antenna element 3908, or vice-versa.
  • the role of the transmit antenna 124 in FIG. 3 may be performed by the active antenna element 3802, and the role of the receive antenna 126 may be performed by the active antenna element 3804, or vice-versa.
  • the role of the transmit antenna 124 in FIG. 3 may be performed by the active antenna element 3902, and the role of the receive antenna 126 may be performed by the active antenna element 3908, or vice-versa.
  • any transmit-receive antenna pair described herein can be implemented with antenna assemblies 3800 or 3900 to permit perturbation of the communication channel and to minimize self-interference during full-duplex communications.
  • a transceiver 4000 includes transmit circuitry 4002 and receive circuitry 4004.
  • the transceiver 4000 is connected to an antenna assembly 4006 through a 2x2 radio-frequency crossbar switch 4008.
  • the antenna assembly 4006 includes a first active antenna element 4008 and a second active antenna element 4010. In a first state of the crossbar switch 4008, the switch connects the first active antenna element 4008 to the transmit circuitry and the second active antenna element 4010 to the receive circuitry.
  • the switch In a second state of the crossbar switch 4008, the switch connects the first active antenna element 4008 to the receive circuitry and the second active antenna element 4010 to the transmit circuitry.
  • the first and second active antenna elements 4008, 4010 may be implemented by, for example, active antenna elements 3802, 3804 of FIG. 38, or by active antenna elements 3902, 3908 of FIG. 39, among other arrangements.
  • step 4100 an outgoing signal is transmitted from a first active antenna element of an antenna assembly operated by a party (e.g., Alice, in the example given above) acting as master.
  • the outgoing signal sent by Alice is looped back by a remote antenna operated by another party (e.g., Bob, in the example given above) acting as slave, and in step 4012, the looped-back signal is received by Alice on a second active antenna element.
  • Alice measures the phase shift between the outgoing signal transmitted from the first antenna element (step 4100) and the incoming signal received on her second antenna element (step 4102). As described in the foregoing embodiments, Alice will subsequently use this measured phase shift to mask future communications with Bob.
  • steps 4100 and 4012 may be performed simultaneously, with Alice continuing to transmit on her first active antenna element while she is receiving the looped-back signal on her second active antenna element.
  • the incoming and outgoing signals in steps 4100 and 4102 may have substantially the same frequency.
  • Alice remodulates the signal from Bob and transmits the remodulated signal on her second active antenna element in step 4112. That is, Alice transmits the outgoing signal on the active antenna element that she had previously used for receiving the incoming signal in step 4102.
  • the incoming signal received in step 4106 has substantially the same frequency as the signal transmitted in step 4112.
  • Alice may buffer the demodulated signal for a predetermined delay period that is known to Alice. This may be done so that Bob does not receive the signal from Alice (sent in step 4112) until after he is finished sending a signal to Alice.
  • the communication channel is perturbed in step 4114 by switching at least one of the switchable radio-frequency reflectors of antenna assembly 3800 or 3900.
  • at least one reflector is switched in each set of switchable radio frequency reflectors.
  • the state of reflectors 3904 and 3910 may both be switched.
  • both parties Alice and Bob
  • the crossbar switch in conjunction with the perturbation of the channel, may also be switched in step 4116 to switch the roles of the active antenna elements.
  • the operations of switching reflectivity and switching the roles of the active antenna elements are performed in a sequence such that each of the active antenna elements transmits only once for each channel configuration.
  • each active antenna element may perform multiple transmissions over the course of a security setup procedure, the channel state is changed at some point between subsequent transmissions of a single active antenna element.
  • Antenna assembly 4200 includes one or more active antenna elements 4202.
  • a plurality of switchable radio frequency reflectors, such as switchable reflector 4204, are arranged in a substantially cylindrical array around the active antenna element 4202.
  • a plurality of non- switchable radio frequency reflectors, such as reflector 4206, are also arranged in a substantially cylindrical array around the active antenna element 4202.
  • the non- switchable radio-frequency reflectors may be metallic strips.
  • the non- switchable radio-frequency reflectors 4206 may be aligned with gaps between the switchable radio-frequency reflectors 4204.
  • the non-switchable radio-frequency reflectors 4206 are arranged at a greater distance from the active antenna element 4202 than the distance of the switchable radio-frequency reflectors 4204.
  • FIG. 43 A plan view of another antenna assembly 4300 according to some embodiments is provided in FIG. 43.
  • Antenna assembly 4300 includes one or more active antenna elements 4302.
  • a plurality of switchable radio frequency reflectors, such as switchable reflector 4304, are arranged in a substantially cylindrical array around the active antenna element 4302.
  • a plurality of non-switchable radio frequency reflectors, such as reflector 4306, are also arranged in a substantially cylindrical array around the active antenna element 4302.
  • the non-switchable radio-frequency reflectors may be metallic strips.
  • the non-switchable radio-frequency reflectors 4306 may be spaced so as to fill gaps between the switchable radio-frequency reflectors 4304 in the cylindrical array.
  • the switchable and non-switchable radio-frequency reflectors are arranged at substantially the same distance from the active antenna element 4302. In some embodiments, gaps between the switchable and non-switchable radio-frequency reflectors are no greater than a quarter wavelength in size.
  • an antenna structure similar to that of assembly 4300 can be constructed using a plurality of wall segments.
  • Wall segment 4400 includes a substrate 4402, which may be printed circuit board (PCB).
  • the wall segment 4400 includes both a switchable and non-switchable radio-frequency reflector on the same substrate 4402.
  • the non-switchable radio-frequency reflector is provided in some embodiments by a metal or other conductive strip 4404 deposited or otherwise applied to the substrate 4402.
  • the non-switchable reflector 4404 preferably has a length greater than one-half wavelength.
  • the switchable radio-frequency reflector is provided with a plurality of conductive segments such as segments 4406, 4408. Each of the individual conductive segments preferably has a length less than a quarter wavelength.
  • Switching components such as switches 4410 and 4412 are provided on the substrate 4402 to provide a switchable connection between consecutive conductive segments.
  • the switching components 4410, 4412 may be solid-state switching components such as PIN diodes.
  • Control circuitry for the switching components (not illustrated) may also be provided on the same substrate 4402.
  • the plurality of conductive segments (including 4406 and 4408) effectively operate as a single conductor.
  • the conductive segments collectively act as a single conductor having a length of at least one-half wavelength.
  • the wall segment 4400 is in communication with propagation perturbation control circuitry 4414.
  • the propagation perturbation control circuitry 4414 may activate the reflectivity of the switchable radio-frequency reflector by applying a forward-biasing voltage across the conductive segments.
  • perturbation control circuitry 4414 may deactivate the reflectivity of the switchable radio- frequency reflector by removing the forward-biasing voltage.
  • a device or structure that is "configured" in a certain way is configured in at least that way, but may also be configured in ways that are not listed.
  • processors such as microprocessors, digital signal processors, customized processors and field programmable gate arrays (FPGAs) and unique stored program instructions (including both software and firmware) that control the one or more processors to implement, in conjunction with certain non-processor circuits, some, most, or all of the functions of the method and/or apparatus described herein.
  • processors or “processing devices”
  • FPGAs field programmable gate arrays
  • unique stored program instructions including both software and firmware
  • some or all functions could be implemented by a state machine that has no stored program instructions, or in one or more application specific integrated circuits (ASICs), in which each function or some combinations of certain of the functions are implemented as custom logic.
  • ASICs application specific integrated circuits
  • an embodiment can be implemented as a computer-readable storage medium having computer readable code stored thereon for programming a computer (e.g., comprising a processor) to perform a method as described and claimed herein.
  • a computer e.g., comprising a processor
  • Examples of such computer- readable storage mediums include, but are not limited to, a hard disk, a CD-ROM, an optical storage device, a magnetic storage device, a ROM (Read Only Memory), a PROM

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  • Engineering & Computer Science (AREA)
  • Computer Security & Cryptography (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

L'invention concerne un ensemble antenne comprenant un premier élément antenne active et un second élément antenne active, pouvant chacun être un dipôle. Un premier groupe de réflecteurs radiofréquence commutables indépendamment est positionné autour d'au moins le premier élément antenne active. Ces premiers réflecteurs radiofréquence commutables peuvent également être positionnés autour du second élément antenne active. En variante, un second groupe de réflecteurs radiofréquence commutables indépendamment peut être positionné autour d'au moins le second élément antenne active. Les réflecteurs commutables permettent une perturbation contrôlée du canal de communication entre l'ensemble antenne et un nœud de communications à distance, permettant des communications chiffrées de manière sécurisée.
PCT/US2014/050968 2013-08-13 2014-08-13 Système d'antenne et procédé de transmission sans fil en duplex intégral avec chiffrement basé sur la phase de canal WO2015023801A1 (fr)

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EP14836322.9A EP3033806A4 (fr) 2013-08-13 2014-08-13 Système d'antenne et procédé de transmission sans fil en duplex intégral avec chiffrement basé sur la phase de canal
CA2921045A CA2921045A1 (fr) 2013-08-13 2014-08-13 Systeme d'antenne et procede de transmission sans fil en duplex integral avec chiffrement base sur la phase de canal

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US201361865221P 2013-08-13 2013-08-13
US61/865,221 2013-08-13
US201361885603P 2013-10-02 2013-10-02
US61/885,603 2013-10-02

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CN116683192B (zh) * 2023-07-04 2024-03-08 北京化工大学 一种基于针织结构的高阶宽带带通小型化频率选择表面

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EP3033806A1 (fr) 2016-06-22
CA2921045A1 (fr) 2015-02-19

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