WO2019006715A1 - Distributed secure beamforming method and apparatus based on feedback control - Google Patents
Distributed secure beamforming method and apparatus based on feedback control Download PDFInfo
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- WO2019006715A1 WO2019006715A1 PCT/CN2017/091913 CN2017091913W WO2019006715A1 WO 2019006715 A1 WO2019006715 A1 WO 2019006715A1 CN 2017091913 W CN2017091913 W CN 2017091913W WO 2019006715 A1 WO2019006715 A1 WO 2019006715A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L7/00—Arrangements for synchronising receiver with transmitter
Definitions
- the present invention relates to the field of communications technologies, and in particular, to a distributed safety beamforming method and apparatus based on feedback control.
- Distributed Beamforming is a cooperative communication technology in which multiple transmitting devices transmit the same information to the target device and control the transmitting phase of the transmitting device to make the signals of multiple transmitting devices at the target end.
- the device is effectively merged.
- phase synchronization algorithms using only single-bit feedback information have been proposed and have been extensively studied.
- the method can realize phase synchronization of the transmitting device to the receiving device through single bit information under a limited feedback channel capacity, but the existing single bit phase synchronization method is only suitable for a reliable communication environment. This method cannot implement distributed secure communication when there is a eavesdropping device stealing information in the environment.
- the embodiment of the invention discloses a distributed safety beamforming method and device based on feedback control, which can realize distributed secure communication and improve the security performance of the distributed secure communication system.
- a first aspect of the embodiments of the present invention discloses a distributed safety beamforming method based on feedback control, which is applied to a transmitting end device included in a distributed secure communication system, where the distributed secure communication system includes a plurality of the transmitting end devices, The receiving end device and the eavesdropping end device, the method comprising:
- a feedback signal where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the nth time slot stored by the receiving end device Whether the second SINR is increased;
- a correlation parameter of transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance
- the nth time slot is a current time slot, and the (n+1)th time slot is the current time slot.
- the next time slot, the n is a positive integer.
- the adjusting, according to the feedback signal, adjusting a correlation parameter of transmitting a weight of the first artificial noise signal in the (n+1)th time slot includes: :
- the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determining
- the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, determining
- the method further includes:
- the device on the transmitting device The number of positive feedback counters is incremented by one;
- the method further includes:
- the transmitting end device is The number of negative feedback counters is incremented by one;
- the method further includes:
- a second aspect of the embodiments of the present invention discloses a distributed safety beamforming method based on feedback control, which is applied to a receiving end device included in a distributed secure communication system, where the distributed secure communication system includes multiple transmitting end devices and a eavesdropping end. Equipment, the method comprising:
- n is the nth time slot is a current time slot, and n is a positive integer.
- the determining, according to the first SINR, the feedback signal includes:
- the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
- the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
- the method further includes include:
- a third aspect of the embodiments of the present invention discloses a distributed security beamforming device, which is used in a transmitting end device included in a distributed secure communication system, and includes:
- a receiving unit configured to receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio (SINR) of the receiving end device in the nth time slot is compared with the receiving end device. Whether the second SINR of the nth time slot is increased;
- SINR signal to interference and noise ratio
- an adjusting unit configured to adjust, according to the feedback signal, a correlation parameter for transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;
- the nth time slot is a current time slot
- the (n+1)th time slot is a next time slot of the current time slot
- the n is a positive integer
- the adjusting unit includes:
- a first determining subunit configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determine
- a second determining subunit configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not improved compared to the second SINR of the nth time slot stored by the receiving end device ,determine
- the distributed safety beamforming device further includes:
- a first counting unit configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is higher than the second SINR of the nth slot stored by the receiving device, The number of positive feedback counters on the transmitting device is accumulated by one;
- the first determining subunit is determined The specific way is:
- the distributed safety beamforming device further includes:
- a second counting unit configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, Adding the number of negative feedback counters on the transmitting device to 1;
- the second determining subunit is determined The specific way is:
- the distributed safety beamforming device further includes:
- a saving unit configured to save the random disturbance of transmitting the weight of the second artificial noise signal in the nth time slot.
- a fourth aspect of the embodiments of the present invention discloses a distributed security beamforming device, which is implemented on a receiving end device included in a distributed secure communication system, and includes:
- a sending unit configured to receive, by the nth time slot, a first signal sent by the multiple sending end devices; where n is the nth time slot is a current time slot, and the n is a positive integer.
- a first determining unit configured to determine, according to the first signal, a first signal to interference and noise ratio SINR in an nth time slot;
- a second determining unit configured to determine, according to the first SINR, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the receiving end Whether the second SINR of the nth slot stored by the device is increased;
- the sending unit is further configured to send the feedback signal to a plurality of the transmitting end devices.
- the determining, by the second determining unit, the feedback signal according to the first SINR includes:
- the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
- the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
- the distributed safety beamforming device further includes:
- a storage unit configured to store a larger SINR of the first SINR and the second SINR as an SINR of the (n+1)th slot of the receiving end device; where the (n+1)th The time slot is the next time slot of the current time slot.
- the embodiment of the invention has the following beneficial effects:
- the transmitting end device may receive the feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared with the Whether the second SINR of the nth time slot stored by the receiving end device is increased; further, the transmitting end device may adjust, according to the feedback signal, the transmitting weight of the first artificial noise signal in the (n+1)th time slot.
- Related parameters including transmit phase, correction factor, and random perturbation.
- the transmitting end device only needs to use the feedback information sent by the receiving end device, and can send the phase of the transmitting weight of the first artificial noise signal to the (n+1)th time slot.
- the off parameter is adjusted to minimize the interference power of the first artificial noise signal at the receiving end device, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
- FIG. 1 is a schematic diagram of a model of a distributed secure communication system according to an embodiment of the present invention
- FIG. 2 is a schematic flow chart of a distributed safety beamforming method based on feedback control according to an embodiment of the present invention
- FIG. 3 is a schematic flow chart of another distributed safety beamforming method based on feedback control disclosed in an embodiment of the present invention.
- FIG. 4 is a schematic flow chart of another distributed safety beamforming method based on feedback control disclosed in an embodiment of the present invention.
- FIG. 5 is a schematic diagram of convergence of a security capacity of a distributed secure communication system according to an embodiment of the present invention.
- FIG. 6 is a schematic structural diagram of a distributed safety beamforming device according to an embodiment of the present invention.
- FIG. 7 is a schematic structural diagram of another distributed safety beamforming device according to an embodiment of the present invention.
- the embodiment of the invention discloses a distributed safety beamforming method and device based on feedback control, which can realize distributed secure communication and improve the security performance of the distributed secure communication system.
- the details are described below in conjunction with the drawings.
- FIG. 1 is a schematic diagram of a model of a distributed secure communication system according to an embodiment of the present invention.
- Each of the transmitting end devices S i and the receiving end device D is equipped with a single antenna, and the eavesdropping device E is equipped with multiple antennas.
- the transmitting device S i is mainly used for transmitting and receiving signals, such as transmitting an artificial noise signal and receiving a feedback signal, and the transmitting device S i may be a base station.
- a base station e.g., an access point
- the base station can refer to a device in an access network that communicates with a wireless terminal over one or more sectors over an air interface.
- the base station can be used to convert the received air frame to the IP packet as a router between the wireless terminal and the rest of the access network, wherein the remainder of the access network can include an Internet Protocol (IP) network.
- IP Internet Protocol
- the base station can also coordinate attribute management of the air interface.
- the base station may be a base station (BTS, Base Transceiver Station) in GSM or CDMA, or may be a base station (NodeB) in WCDMA, or may be an evolved base station in LTE (NodeB or eNB or e-NodeB, evolutional Node B), the embodiment of the present invention is not limited.
- BTS Base Transceiver Station
- NodeB base station
- NodeB evolved base station
- LTE NodeB or eNB or e-NodeB, evolutional Node B
- the receiving device D is mainly used for transmitting and receiving signals, such as transmitting an artificial noise signal and receiving a useful signal, and the target device D may be a base station.
- the eavesdropping device E is mainly used for monitoring the signal sent by the transmitting end device S i to the receiving end device D, and monitoring the signal sent by the receiving end device D to the transmitting end device S i , and adjusting its own beamforming according to the received signal.
- the eavesdropping device E may include, but is not limited to, a base station, a user equipment, a communication vehicle, and the like.
- the coordinates of the receiving device D are represented as (0, r D ), and the coordinates of the eavesdropping device E are expressed as (r E sin ⁇ E , r E cos ⁇ E ), where ⁇ E represents the angle between the eavesdropping device E and the y-axis at the coordinates shown in FIG. N
- distributed transmitting devices that have been frequency-synchronized are randomly distributed in a circle with a radius of r S , and the distribution rules of these transmitting devices are uniformly distributed, that is, each distributed transmitting device appears at any position in the circle. The probability is the same.
- ⁇ represents the carrier wavelength
- Indicates the free space path loss of the i-th transmitter device to the eavesdropping device E Indicates the distance from the i-th transmitter device to the eavesdrop device E.
- h DE represents the channel fading between the receiving device D and the eavesdropping device E. Similar to the above definition method, It indicates the free space path loss, distance, and channel fading between the receiving device D and the ith transmitting device when transmitting the feedback signal, respectively.
- the transmitting end device may receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the receiving end device is in the first time slot of the nth time slot. Whether the noise ratio SINR is higher than the second SINR of the nth slot stored by the receiving end device; further, the transmitting end device may adjust the (n+1)th time according to the feedback signal.
- the slot transmits a correlation parameter of the transmission weight of the first artificial noise signal to minimize the interference power of the third artificial noise signal at the receiving end device, thereby improving the security of the distributed secure communication system.
- FIG. 2 is a schematic flowchart diagram of a distributed safety beamforming method based on feedback control according to an embodiment of the present invention.
- the distributed safety beamforming method based on feedback control is applied to a transmitting end device included in the distributed secure communication system.
- the distributed safety beamforming method based on feedback control may include the following steps:
- Step 201 The transmitting end device receives the feedback signal sent by the receiving end device.
- the feedback signal is used to indicate whether the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device.
- the nth time slot is a current time slot, and the n is a positive integer.
- the transmitting end device may further send the first signal carrying the second artificial noise signal to the receiving end device in the nth time slot.
- the second artificial noise signal is used to interfere with the estimation accuracy of the first channel direction information by the eavesdropping device.
- the transmitting, by the transmitting device, the first signal carrying the second artificial noise signal to the receiving device in the nth time slot may be expressed as:
- x C [n] represents the secret information transmitted in the nth time slot
- the secret information transmitted by each distributed transmitting end device in each time slot is the same.
- all distributed transmitting devices transmit the same power of the secret information x C [n] in each time slot, transmit the second artificial noise ⁇ S, i [n] have the same power, and they satisfy the following conditions:
- P T represents the upper limit of the sum of the power of the secret information x C [n] and the second artificial noise ⁇ S, i [n] transmitted by each distributed transmitting device.
- the transmit weight can be expressed as
- the receiving end device may send feedback information to the transmitting end device according to the first signal, where the ith distributed transmitting end
- the feedback signal received by device S i can be expressed as:
- x D [n] is a feedback signal determined by the receiving device
- P C2 indicates that the receiving device D feeds back the transmission power of the single bit control information x B [n]
- P ⁇ 2 indicates that the receiving device D transmits the power of the second artificial noise signal ⁇ D [n], ⁇ D [n] to CN ( 0,1).
- Indicates the phase response of the channel when the control information is fed back between the receiving device D and the i-th distributed transmitting device S i Represents additive white Gaussian noise on the ith distributed transmitter device.
- Step 202 If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, the transmitting end device determines
- Step 203 The transmitting device adds 1 to the number of positive feedback counters on the transmitting device.
- Step 204 If the number of accumulated positive feedback counters is greater than or equal to the first accumulated threshold, the transmitting device determines
- the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, and the accumulated positive feedback is performed. If the number of counters is greater than or equal to the first accumulated threshold, the transmitting device needs to update and determine Conversely, the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, and the accumulated positive feedback is performed. The number of counters is less than the first accumulated threshold, and the transmitting device does not need to update and determine
- positive feedback is accumulated. If a negative feedback occurs between the two positive feedbacks, the positive feedback is interrupted, and the positive feedback counter is unclear.
- Step 205 The transmitting device saves the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot, and ends the process.
- the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is higher than the second SINR of the nth slot stored by the receiving end device.
- the transmitting device needs to save the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot to prepare for updating the correction factor in the (n+1)th time slot.
- Step 206 If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not higher than the second SINR of the nth slot stored by the receiving end device, the transmitting end device determines
- Step 207 The transmitting device adds 1 to the number of negative feedback counters on the transmitting device.
- Step 208 If the number of accumulated negative feedback counters is greater than or equal to the second accumulated threshold, the transmitting device determines
- the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not increased compared to the second SINR of the nth slot stored by the receiving device, and the accumulated negative If the number of feedback counters is greater than or equal to the second accumulated threshold, the transmitting device needs to update and determine Conversely, the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not increased compared to the second SINR of the nth slot stored by the receiving device, and the accumulated negative When the number of feedback counters is less than the second accumulated threshold, the transmitting device does not need to update and determine
- the negative feedback counter it is continuous negative feedback. If the negative feedback is interrupted by a positive feedback, the negative feedback counter should be cleared to 0.
- the transmitting end device may receive the feedback signal sent by the receiving end device, where the feedback signal is used to indicate the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot. Whether the second SINR of the nth time slot stored by the receiving end device is increased; further, the transmitting end device may adjust the (n+1)th time slot to send the first artificial noise signal according to the feedback signal.
- the transmit phase, the correction factor, and the random disturbance of the transmit weight are such that the interference power of the third artificial noise signal at the receiving device is minimized, thereby improving the security of the distributed secure communication system.
- FIG. 3 is a schematic flowchart diagram of another distributed safety beamforming method based on feedback control according to an embodiment of the present invention.
- the distributed safety beamforming method based on feedback control is applied to a receiving end device included in the distributed secure communication system.
- the distributed safety beamforming method based on feedback control may include the following steps:
- Step 301 The receiving end device receives, in the nth time slot, a plurality of first signals sent by the transmitting end device.
- the n is the current time slot, and the n is a positive integer.
- the receiving end device receives, in the nth time slot, a plurality of first signals sent by the transmitting end device, which may be represented as
- Step 302 The receiving end device determines, according to the first signal, a first signal to interference and noise ratio SINR in the nth time slot.
- the signal to interference and noise ratio of the receiving device in the nth time slot can be expressed as:
- the amount of mutual information R D [n] between the transmitting device and the receiving device in the nth time slot can be expressed as:
- the safety capacity R S [n] on the receiving device D can be expressed as:
- Step 303 The receiving end device determines a feedback signal according to the first SINR.
- the feedback signal is used to indicate whether the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device;
- Determining, by the receiving device, the feedback signal according to the first SINR includes:
- the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
- the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
- the feedback signal determined by the receiving device can be expressed as:
- P C2 indicates that the receiving device D feeds back the transmission power of the single bit control information x B [n]
- P ⁇ 2 indicates that the receiving device D transmits the power of the third artificial noise signal ⁇ D [n], ⁇ D [n] ⁇ CN (0,1).
- bit 1 may be used to indicate that the first SINR is compared to the second SINR, and is referred to as single-bit positive feedback, and bit 0 indicates that the first SINR is not improved compared to the second SINR. And call it a single-bit negative feedback.
- the receiving end device only needs to feed back single-bit control information, which can save network resources.
- Step 304 The receiving end device sends the feedback signal to a plurality of the transmitting end devices.
- Step 305 The receiving end device stores the larger SINR of the first SINR and the second SINR as the SINR of the (n+1)th slot of the receiving end device.
- the (n+1)th time slot is the next time slot of the current time slot.
- the receiving end device may receive the first signal sent by the multiple transmitting end devices in the nth time slot; and determine the first information in the nth time slot according to the first signal. a dry noise ratio SINR; and after determining the feedback signal according to the first SINR, transmitting the feedback signal to a plurality of the transmitting end devices, so that the transmitting end device can adjust the (n+1)th time according to the feedback signal
- the slot transmits the transmit phase, the correction factor, and the random disturbance of the transmit weight of the first artificial noise signal, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
- FIG. 4 is a schematic flowchart diagram of another distributed safety beamforming method based on feedback control according to an embodiment of the present invention; wherein the distributed safety beamforming method based on feedback control is from a transmitting device and For some or all of the steps in FIG. 4, the description in FIG. 2 or FIG. 3 may be referred to, and details are not described herein again.
- the feedback-based distributed safety beamforming method may include the following steps:
- Step 401 The transmitting end device sends the first signal to the receiving end device in the nth time slot.
- Step 402 The receiving end device determines, according to the first signal, a first signal to interference and noise ratio SINR in the nth time slot.
- Step 403 The receiving end device determines a feedback signal according to the first SINR.
- Step 404 The receiving end device sends the feedback signal to a plurality of the transmitting end devices.
- Step 405 The transmitting end device adjusts, according to the feedback signal, a transmitting phase, a correction factor, and a random disturbance of transmitting the transmission weight of the first artificial noise signal in the (n+1)th time slot.
- FIG. 5 is a schematic diagram of convergence of a secure capacity of a distributed secure communication system according to an embodiment of the present invention. As shown in FIG. 5, the security capacity of the distributed secure communication system is significantly improved after the iteration ends. The more the number of transmitting devices, the higher the confidential capacity of the distributed secure communication system.
- the transmitting device may send the first signal to the receiving device in the nth time slot, and the receiving device determines the first signal to interference and noise ratio SINR in the nth time slot according to the first signal, and according to the first SINR Determining a feedback signal and transmitting the feedback signal to a plurality of the transmitting end devices, and the transmitting end device may adjust the transmitting weight of the first artificial noise signal in the (n+1)th time slot according to the feedback signal.
- the transmission phase, the correction factor, and the random disturbance are such that the interference power of the third artificial noise signal at the receiving end device is minimized, thereby improving the security of the distributed secure communication system.
- FIG. 6 is a schematic structural diagram of a distributed safety beamforming apparatus according to an embodiment of the present invention.
- the distributed safety beamforming device described in FIG. 6 can be implemented in a transmitting end device included in the distributed secure communication system, and the distributed safety beam forming device described in FIG. 6 can be used to perform the description described in FIG. 2 or FIG.
- the distributed safety beamforming device can include:
- the receiving unit 601 is configured to receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared with the receiving end device. Whether the second SINR of the stored nth slot is increased;
- the adjusting unit 602 is configured to adjust, according to the feedback signal, a correlation parameter for transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;
- the nth time slot is a current time slot
- the (n+1)th time slot is a next time slot of the current time slot
- the n is a positive integer
- the adjusting unit 602 includes:
- a first determining sub-unit 6021 configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device ,determine
- a second determining sub-unit 6022 configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is smaller than the second SINR of the nth slot stored by the receiving end device Upgrade, determine
- the distributed safety beamforming device further includes:
- a first counting unit 603, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, Adding the number of positive feedback counters on the transmitting device to 1;
- the first determining subunit 6021 determines The specific way is:
- the distributed safety beamforming device further includes:
- the second counting unit 604 is configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not improved compared to the second SINR of the nth time slot stored by the receiving end device Adding the number of negative feedback counters on the transmitting device to 1;
- the second determining subunit 6022 determines The specific way is:
- the distributed safety beamforming device further includes:
- the saving unit 605 is configured to save the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot.
- the transmitting end device may receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate the first letter of the receiving end device in the nth time slot. Whether the dry-noise ratio SINR is higher than the second SINR of the n-th slot stored by the receiving device; further, the transmitting device may adjust the (n+1)th slot to send the first according to the feedback signal.
- the transmitting end device only needs to use the feedback information sent by the receiving end device, and can adjust the relevant parameters of the transmitting weight of the first artificial noise signal in the (n+1)th time slot to The interference power of the first artificial noise signal at the receiving end device is minimized, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
- FIG. 7 is a schematic structural diagram of another distributed safety beamforming apparatus according to an embodiment of the present invention.
- the distributed safety beamforming device described in FIG. 7 operates on a receiving end device included in the distributed secure communication system, and the distributed safety beamforming device described in FIG. 7 can be used to perform the method described in FIG. 3 or FIG.
- the distributed safety beamforming device can include:
- the sending unit 701 is configured to receive, by the nth time slot, a plurality of first signals sent by the transmitting end device, where n is the nth time slot is a current time slot, and the n is a positive integer.
- a first determining unit 702 configured to determine, according to the first signal, a first letter in an nth time slot Dry noise ratio SINR;
- a second determining unit 703 configured to determine, according to the first SINR, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the receiving Whether the second SINR of the nth slot stored by the end device is increased;
- the sending unit 701 is further configured to send the feedback signal to multiple sending end devices.
- the determining, by the second determining unit 703, the feedback signal according to the first SINR includes:
- the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
- the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
- the distributed safety beamforming device further includes:
- the storage unit 704 is configured to store the SINR of the first SINR and the second SINR as the SINR of the (n+1)th slot of the receiving end device; where the (n+1) The time slot is the next time slot of the current time slot.
- the receiving end device may receive the first signal sent by the plurality of transmitting end devices in the nth time slot; and determine the nth time slot according to the first signal.
- the first signal to interference and noise ratio SINR and after determining the feedback signal according to the first SINR, sending the feedback signal to a plurality of the transmitting end devices, so that the transmitting end device can adjust the first according to the feedback signal.
- the time slot transmits the transmission phase, the correction factor and the random disturbance of the transmission weight of the first artificial noise signal, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
- the disclosed device can be Other ways to achieve.
- the device embodiments described above are merely illustrative.
- the division of the unit is only a logical function division.
- there may be another division manner for example, multiple units or components may be combined or may be Integrate into another system, or some features can be ignored or not executed.
- the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be electrical or otherwise.
- the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
- each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
- the above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
- the integrated unit if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable memory. Based on such understanding, the technical solution of the present invention may contribute to the prior art or all or part of the technical solution may be embodied in the form of a software product stored in a memory. A number of instructions are included to cause a computer device (which may be a personal computer, server or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention.
- the foregoing memory includes: a U disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a removable hard disk, a magnetic disk, or an optical disk, and the like, which can store program codes.
- ROM Read-Only Memory
- RAM Random Access Memory
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Abstract
The present invention provides a distributed secure beamforming method and apparatus based on feedback control. The method comprises: receiving feedback signals sent by a receiving end device, the feedback signals being used for indicating whether a first signal to interference plus noise ratio (SINR) of the receiving end device on a nth timeslot is enhanced relative to a second SINR stored by the receiving end device on the nth timeslot; and adjusting, according to the feedback signals, relevant parameters of a transmission weight of first artificial noise signals sent on a (n+1)th timeslot, the relevant parameters comprising a transmission phase, a correction factor and a random disturbance. By means of embodiments of the present invention, distributed secure communication can be implemented, and the secrecy performance of a distributed secure communication system is improved.
Description
本发明涉及通信技术领域,尤其涉及一种基于反馈控制的分布式安全波束成型方法及装置。The present invention relates to the field of communications technologies, and in particular, to a distributed safety beamforming method and apparatus based on feedback control.
分布式波束成型(Distributed Beamforming)是一种协同通信技术,由多个发射端设备发送相同的信息给目标端设备,并通过控制发射端设备的发射相位使多个发射端设备的信号在目标端设备进行有效的合并。Distributed Beamforming is a cooperative communication technology in which multiple transmitting devices transmit the same information to the target device and control the transmitting phase of the transmitting device to make the signals of multiple transmitting devices at the target end. The device is effectively merged.
近年来,只利用单比特反馈信息的相位同步算法被提出,并得到了广泛的研究。该方法可以在有限的反馈信道容量下,通过单比特信息实现发射端设备到接收端设备的相位同步,但是现有的单比特相位同步方法只适用于可靠的通信环境。当环境中有窃听端设备窃取信息时,该方法不能实现分布式安全通信。In recent years, phase synchronization algorithms using only single-bit feedback information have been proposed and have been extensively studied. The method can realize phase synchronization of the transmitting device to the receiving device through single bit information under a limited feedback channel capacity, but the existing single bit phase synchronization method is only suitable for a reliable communication environment. This method cannot implement distributed secure communication when there is a eavesdropping device stealing information in the environment.
发明内容Summary of the invention
本发明实施例公开了一种基于反馈控制的分布式安全波束成型方法及装置,能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。The embodiment of the invention discloses a distributed safety beamforming method and device based on feedback control, which can realize distributed secure communication and improve the security performance of the distributed secure communication system.
本发明实施例第一方面公开一种基于反馈控制的分布式安全波束成型方法,应用于分布式安全通信***包括的发射端设备,所述分布式安全通信***包括多个所述发射端设备、接收端设备以及窃听端设备,所述方法包括:A first aspect of the embodiments of the present invention discloses a distributed safety beamforming method based on feedback control, which is applied to a transmitting end device included in a distributed secure communication system, where the distributed secure communication system includes a plurality of the transmitting end devices, The receiving end device and the eavesdropping end device, the method comprising:
接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;Receiving, by the receiving end device, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the nth time slot stored by the receiving end device Whether the second SINR is increased;
根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动;And adjusting, according to the feedback signal, a correlation parameter of transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;
其中,所述第n时隙为当前时隙,所述第(n+1)时隙为所述当前时隙
的下一个时隙,所述n为正整数。The nth time slot is a current time slot, and the (n+1)th time slot is the current time slot.
The next time slot, the n is a positive integer.
作为一种可选的实施方式,在本发明实施例第一方面中,所述根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数包括:As an optional implementation manner, in the first aspect of the embodiment of the present invention, the adjusting, according to the feedback signal, adjusting a correlation parameter of transmitting a weight of the first artificial noise signal in the (n+1)th time slot includes: :
若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,确定
If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determining
若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,确定
If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, determining
其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,为随机扰动步长的增长因子,为随机扰动步长的下降因子。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, Transmitting a random perturbation of the transmission weight of the second artificial noise signal for the nth time slot, Random disturbance step Growth factor, Random disturbance step Declining factor.
作为一种可选的实施方式,在本发明实施例第一方面中,所述方法还包括:As an optional implementation manner, in the first aspect of the embodiments of the present invention, the method further includes:
若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,将所述发射端设备上的正反馈计数器的个数累加1;If the feedback signal is used to indicate that the first SINR of the receiving device in the nth slot is higher than the second SINR of the nth slot stored by the receiving device, the device on the transmitting device The number of positive feedback counters is incremented by one;
若累加后的正反馈计数器的个数大于或等于第一累加阈值,则执行所述的确定
Performing the determination if the number of accumulated positive feedback counters is greater than or equal to the first accumulated threshold
作为一种可选的实施方式,在本发明实施例第一方面中,所述方法还包括:As an optional implementation manner, in the first aspect of the embodiments of the present invention, the method further includes:
若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,将所述发射端设备上的负反馈计数器的个数累加1;If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, the transmitting end device is The number of negative feedback counters is incremented by one;
若累加后的负反馈计数器的个数大于或等于第二累加阈值,则执行所述的确定
Performing the determination if the number of accumulated negative feedback counters is greater than or equal to the second accumulated threshold
作为一种可选的实施方式,在本发明实施例第一方面中,所述方法还包括:As an optional implementation manner, in the first aspect of the embodiments of the present invention, the method further includes:
保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。And storing the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot.
本发明实施例第二方面公开一种基于反馈控制的分布式安全波束成型方法,应用于分布式安全通信***包括的接收端设备,所述分布式安全通信***包括多个发射端设备以及窃听端设备,所述方法包括:A second aspect of the embodiments of the present invention discloses a distributed safety beamforming method based on feedback control, which is applied to a receiving end device included in a distributed secure communication system, where the distributed secure communication system includes multiple transmitting end devices and a eavesdropping end. Equipment, the method comprising:
在第n时隙接收多个所述发射端设备发送的第一信号;其中,所述n为所述第n时隙为当前时隙,所述n为正整数。Receiving, by the nth time slot, a plurality of first signals sent by the transmitting end device; where n is the nth time slot is a current time slot, and n is a positive integer.
根据所述第一信号,确定在第n时隙的第一信干噪比SINR;Determining, according to the first signal, a first signal to interference and noise ratio SINR in the nth time slot;
根据所述第一SINR,确定反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;And determining, according to the first SINR, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the nth time slot stored by the receiving end device. Whether the second SINR is increased;
向多个所述发射端设备发送所述反馈信号。Transmitting the feedback signal to a plurality of the transmitting end devices.
作为一种可选的实施方式,在本发明实施例第二方面中,所述根据所述第一SINR,确定反馈信号包括:As an optional implementation manner, in the second aspect of the embodiment of the present invention, the determining, according to the first SINR, the feedback signal includes:
将所述第一SINR与所述第二SINR进行比较;Comparing the first SINR with the second SINR;
若所述第一SINR大于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR提升的反馈信号;If the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
若所述第一SINR小于或等于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR未提升的反馈信号。If the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
作为一种可选的实施方式,在本发明实施例第二方面中,所述方法还包
括:As an optional implementation manner, in the second aspect of the embodiment of the present invention, the method further includes
include:
将所述第一SINR与所述第二SINR中较大的SINR存储为所述接收端设备第(n+1)时隙的SINR;其中,所述第(n+1)时隙为所述当前时隙的下一个时隙。And storing the SINR of the first SINR and the second SINR as the SINR of the (n+1)th slot of the receiving end device; wherein the (n+1)th slot is the The next time slot of the current time slot.
本发明实施例第三方面公开一种分布式安全波束成型装置,运行于分布式安全通信***包括的发射端设备,包括:A third aspect of the embodiments of the present invention discloses a distributed security beamforming device, which is used in a transmitting end device included in a distributed secure communication system, and includes:
接收单元,用于接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;a receiving unit, configured to receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio (SINR) of the receiving end device in the nth time slot is compared with the receiving end device. Whether the second SINR of the nth time slot is increased;
调整单元,用于根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动;And an adjusting unit, configured to adjust, according to the feedback signal, a correlation parameter for transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;
其中,所述第n时隙为当前时隙,所述第(n+1)时隙为所述当前时隙的下一个时隙,所述n为正整数。The nth time slot is a current time slot, the (n+1)th time slot is a next time slot of the current time slot, and the n is a positive integer.
作为一种可选的实施方式,在本发明实施例第三方面中,所述调整单元包括:As an optional implementation manner, in the third aspect of the embodiment of the present invention, the adjusting unit includes:
第一确定子单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,确定
a first determining subunit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determine
第二确定子单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,确定
a second determining subunit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not improved compared to the second SINR of the nth time slot stored by the receiving end device ,determine
其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,为
随机扰动步长的增长因子,为随机扰动步长的下降因子。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, Transmitting a random perturbation of the transmission weight of the second artificial noise signal for the nth time slot, Random disturbance step Growth factor, Random disturbance step Declining factor.
作为一种可选的实施方式,在本发明实施例第三方面中,所述分布式安全波束成型装置还包括:As an optional implementation manner, in the third aspect of the embodiments of the present invention, the distributed safety beamforming device further includes:
第一计数单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,将所述发射端设备上的正反馈计数器的个数累加1;a first counting unit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is higher than the second SINR of the nth slot stored by the receiving device, The number of positive feedback counters on the transmitting device is accumulated by one;
若累加后的正反馈计数器的个数大于或等于第一累加阈值,确定
If the number of accumulated positive feedback counters is greater than or equal to the first accumulated threshold, determine
作为一种可选的实施方式,在本发明实施例第三方面中,所述分布式安全波束成型装置还包括:As an optional implementation manner, in the third aspect of the embodiments of the present invention, the distributed safety beamforming device further includes:
第二计数单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,将所述发射端设备上的负反馈计数器的个数累加1;a second counting unit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, Adding the number of negative feedback counters on the transmitting device to 1;
若累加后的负反馈计数器的个数大于或等于第二累加阈值,则执行所述的确定
Performing the determination if the number of accumulated negative feedback counters is greater than or equal to the second accumulated threshold
作为一种可选的实施方式,在本发明实施例第三方面中,所述分布式安全波束成型装置还包括:As an optional implementation manner, in the third aspect of the embodiments of the present invention, the distributed safety beamforming device further includes:
保存单元,用于保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。And a saving unit, configured to save the random disturbance of transmitting the weight of the second artificial noise signal in the nth time slot.
本发明实施例第四方面公开一种分布式安全波束成型装置,运行于分布式安全通信***包括的接收端设备,包括:A fourth aspect of the embodiments of the present invention discloses a distributed security beamforming device, which is implemented on a receiving end device included in a distributed secure communication system, and includes:
发送单元,用于在第n时隙接收多个所述发射端设备发送的第一信号;其中,所述n为所述第n时隙为当前时隙,所述n为正整数。
And a sending unit, configured to receive, by the nth time slot, a first signal sent by the multiple sending end devices; where n is the nth time slot is a current time slot, and the n is a positive integer.
第一确定单元,用于根据所述第一信号,确定在第n时隙的第一信干噪比SINR;a first determining unit, configured to determine, according to the first signal, a first signal to interference and noise ratio SINR in an nth time slot;
第二确定单元,用于根据所述第一SINR,确定反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;a second determining unit, configured to determine, according to the first SINR, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the receiving end Whether the second SINR of the nth slot stored by the device is increased;
所述发送单元,还用于向多个所述发射端设备发送所述反馈信号。The sending unit is further configured to send the feedback signal to a plurality of the transmitting end devices.
作为一种可选的实施方式,在本发明实施例第四方面中,所述第二确定单元根据所述第一SINR,确定反馈信号包括:As an optional implementation manner, in the fourth aspect of the embodiment of the present invention, the determining, by the second determining unit, the feedback signal according to the first SINR includes:
将所述第一SINR与所述第二SINR进行比较;Comparing the first SINR with the second SINR;
若所述第一SINR大于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR提升的反馈信号;If the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
若所述第一SINR小于或等于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR未提升的反馈信号。If the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
作为一种可选的实施方式,在本发明实施例第四方面中,所述分布式安全波束成型装置还包括:As an optional implementation manner, in the fourth aspect of the embodiments of the present invention, the distributed safety beamforming device further includes:
存储单元,用于将所述第一SINR与所述第二SINR中较大的SINR存储为所述接收端设备第(n+1)时隙的SINR;其中,所述第(n+1)时隙为所述当前时隙的下一个时隙。a storage unit, configured to store a larger SINR of the first SINR and the second SINR as an SINR of the (n+1)th slot of the receiving end device; where the (n+1)th The time slot is the next time slot of the current time slot.
与现有技术相比,本发明实施例具备以下有益效果:Compared with the prior art, the embodiment of the invention has the following beneficial effects:
本发明实施例中,发射端设备可以接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;进一步地,发射端设备可以根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动。可见,实施本发明实施例,发射端设备只需要使用接收端设备发送的反馈信息,就可以对第(n+1)时隙发送第一人工噪声信号的发射权值的相
关参数进行调整,以使所述第一人工噪声信号在所述接收端设备的干扰功率最小,从而能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。In the embodiment of the present invention, the transmitting end device may receive the feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared with the Whether the second SINR of the nth time slot stored by the receiving end device is increased; further, the transmitting end device may adjust, according to the feedback signal, the transmitting weight of the first artificial noise signal in the (n+1)th time slot. Related parameters, including transmit phase, correction factor, and random perturbation. It can be seen that, in the embodiment of the present invention, the transmitting end device only needs to use the feedback information sent by the receiving end device, and can send the phase of the transmitting weight of the first artificial noise signal to the (n+1)th time slot.
The off parameter is adjusted to minimize the interference power of the first artificial noise signal at the receiving end device, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
为了更清楚地说明本发明实施例中的技术方案,下面将对实施例中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings to be used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the present invention. Those skilled in the art can also obtain other drawings based on these drawings without paying any creative work.
图1是本发明实施例公开的一种分布式安全通信***的模型示意图;1 is a schematic diagram of a model of a distributed secure communication system according to an embodiment of the present invention;
图2是本发明实施例公开的一种基于反馈控制的分布式安全波束成型方法的流程示意图;2 is a schematic flow chart of a distributed safety beamforming method based on feedback control according to an embodiment of the present invention;
图3是本发明实施例公开的另一种基于反馈控制的分布式安全波束成型方法的流程示意图;3 is a schematic flow chart of another distributed safety beamforming method based on feedback control disclosed in an embodiment of the present invention;
图4是本发明实施例公开的另一种基于反馈控制的分布式安全波束成型方法的流程示意图;4 is a schematic flow chart of another distributed safety beamforming method based on feedback control disclosed in an embodiment of the present invention;
图5是本发明实施例公开的一种分布式安全通信***的保密容量的收敛示意图;FIG. 5 is a schematic diagram of convergence of a security capacity of a distributed secure communication system according to an embodiment of the present invention; FIG.
图6是本发明实施例公开的一种分布式安全波束成型装置的结构示意图;6 is a schematic structural diagram of a distributed safety beamforming device according to an embodiment of the present invention;
图7是本发明实施例公开的另一种分布式安全波束成型装置的结构示意图。FIG. 7 is a schematic structural diagram of another distributed safety beamforming device according to an embodiment of the present invention.
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅是本发明一部分实施例,而不是全部的实施例。基于本发明中的实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的范围。The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts are within the scope of the present invention.
需要说明的是,本发明的说明书和权利要求书及上述附图中的术语“第
一”和“第二”等是用于区别不同对象,而不是用于描述特定顺序。此外,术语“包括”和“具有”以及它们任何变形,意图在于覆盖不排他的包含。例如包含了一系列步骤或单元的过程、方法、***、产品或设备没有限定于已列出的步骤或单元,而是可选地还包括没有列出的步骤或单元,或可选地还包括对于这些过程、方法、产品或设备固有的其它步骤或单元。It should be noted that the term "the first" in the specification and claims of the present invention and the above drawings
The use of the terms "comprising" and "comprising", and the meaning of the meaning of the meaning The processes, methods, systems, products, or devices of the series of steps or units are not limited to the listed steps or units, but optionally also include steps or units not listed, or alternatively also for such processes, Other steps or units inherent to the method, product or device.
本发明实施例公开了一种基于反馈控制的分布式安全波束成型方法及装置,能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。以下进行结合附图进行详细描述。The embodiment of the invention discloses a distributed safety beamforming method and device based on feedback control, which can realize distributed secure communication and improve the security performance of the distributed secure communication system. The details are described below in conjunction with the drawings.
请参阅图1,图1是本发明实施例公开的一种分布式安全通信***的模型示意图。如图1所示,该分布式安全通信***包括多个发射端设备Si(i=1,2,3....N,且N为正整数)、接收端设备D以及窃听端设备E。其中,每个发射端设备Si与接收端设备D装备单天线,窃听端设备E装备多天线。Please refer to FIG. 1. FIG. 1 is a schematic diagram of a model of a distributed secure communication system according to an embodiment of the present invention. As shown in FIG. 1, the distributed secure communication system includes a plurality of transmitting end devices S i (i=1, 2, 3....N, and N is a positive integer), a receiving end device D, and a eavesdropping device E. . Each of the transmitting end devices S i and the receiving end device D is equipped with a single antenna, and the eavesdropping device E is equipped with multiple antennas.
其中,发射端设备Si主要用于收发信号,比如发送人工噪声信号以及接收反馈信号等,该发射端设备Si可以为基站。基站(例如接入点)可以是指接入网中在空中接口上通过一个或多个扇区与无线终端通信的设备。基站可用于将收到的空中帧与IP分组进行相互转换,作为无线终端与接入网的其余部分之间的路由器,其中,接入网的其余部分可包括网际协议(IP)网络。基站还可以协调对空中接口的属性管理。例如,基站可以是GSM或CDMA中的基站(BTS,Base Transceiver Station),也可以是WCDMA中的基站(NodeB),还可以是LTE中的演进型基站(NodeB或eNB或e-NodeB,evolutional Node B),本发明实施例不做限定。The transmitting device S i is mainly used for transmitting and receiving signals, such as transmitting an artificial noise signal and receiving a feedback signal, and the transmitting device S i may be a base station. A base station (e.g., an access point) can refer to a device in an access network that communicates with a wireless terminal over one or more sectors over an air interface. The base station can be used to convert the received air frame to the IP packet as a router between the wireless terminal and the rest of the access network, wherein the remainder of the access network can include an Internet Protocol (IP) network. The base station can also coordinate attribute management of the air interface. For example, the base station may be a base station (BTS, Base Transceiver Station) in GSM or CDMA, or may be a base station (NodeB) in WCDMA, or may be an evolved base station in LTE (NodeB or eNB or e-NodeB, evolutional Node B), the embodiment of the present invention is not limited.
其中,接收端设备D主要用于收发信号,比如发送人工噪声信号以及接收有用信号等,该目标端设备D可以为基站。The receiving device D is mainly used for transmitting and receiving signals, such as transmitting an artificial noise signal and receiving a useful signal, and the target device D may be a base station.
其中,窃听设备E主要用于监听发射端设备Si发送给接收端设备D的信号,以及监听接收端设备D发送给发射端设备Si的信号,并根据接收到的信号调整自身的波束成型器,该窃听设备E可以包括但不限于基站、用户设备、通信车等。
The eavesdropping device E is mainly used for monitoring the signal sent by the transmitting end device S i to the receiving end device D, and monitoring the signal sent by the receiving end device D to the transmitting end device S i , and adjusting its own beamforming according to the received signal. The eavesdropping device E may include, but is not limited to, a base station, a user equipment, a communication vehicle, and the like.
在图1所示的分布式安全通信***中,接收端设备D的坐标表示为(0,rD),窃听端设备E的坐标表示为(rE sinθE,rE cosθE),其中θE表示在图1所示的坐标下,窃听端设备E与y轴之间的夹角。N个已经经过频率同步的分布式发射端设备随机分布在半径为rS的圆中,同时这些发射端设备的分布规律符合均匀分布,即每一个分布式发射端设备在圆中任一位置出现的概率相同。其中,第i个发射端设备Si(i=1,2,K,N)的坐标可以表示为因此,第i个发射端设备到接收端设备D的自由空间路径损耗为式中λ表示载波波长,表示第i个发射端设备到接收端设备D的距离。表示第i个发射端设备到接收端设备D的信道衰落。表示第i个发射端设备到窃听端设备E的自由空间路径损耗,式中表示第i个发射端设备到窃听端设备E的距离,表示第i个发射端设备到窃听端设备E的信道衰落。LDE=λ/4πdDE表示接收端设备D与窃听端设备E之间的自由空间路径损耗,则表示接收端设备D与窃听端设备E之间的距离。hDE则表示接收端设备D与窃听端设备E之间的信道衰落。类似于以上的定义方法,分别表示接收端设备D在发送反馈信号时与第i个发射端设备间的自由空间路径损耗、距离以及信道衰落。In the distributed secure communication system shown in FIG. 1, the coordinates of the receiving device D are represented as (0, r D ), and the coordinates of the eavesdropping device E are expressed as (r E sin θ E , r E cos θ E ), where θ E represents the angle between the eavesdropping device E and the y-axis at the coordinates shown in FIG. N distributed transmitting devices that have been frequency-synchronized are randomly distributed in a circle with a radius of r S , and the distribution rules of these transmitting devices are uniformly distributed, that is, each distributed transmitting device appears at any position in the circle. The probability is the same. The coordinates of the i-th transmitting end device S i (i=1, 2, K, N) can be expressed as Therefore, the free space path loss of the i-th transmitting end device to the receiving end device D is Where λ represents the carrier wavelength, Indicates the distance from the i-th transmitter device to the sink device D. Indicates channel fading from the i-th transmitter device to the sink device D. Indicates the free space path loss of the i-th transmitter device to the eavesdropping device E, Indicates the distance from the i-th transmitter device to the eavesdrop device E. Indicates the channel fading of the i-th transmitter device to the eavesdropping device E. L DE = λ / 4πd DE represents the free space path loss between the receiving device D and the eavesdropping device E, It represents the distance between the receiving device D and the eavesdropping device E. h DE represents the channel fading between the receiving device D and the eavesdropping device E. Similar to the above definition method, It indicates the free space path loss, distance, and channel fading between the receiving device D and the ith transmitting device when transmitting the feedback signal, respectively.
其中,任一分布式发射端设备Si(i=1,2,K,N)与接收端设备D都装备全向单天线,窃听端设备E上则装备了多天线阵列以获取更多的信道方向信息,从而提升窃听端设备E自身的窃听容量,例如通过估计分布式发射端设备与接收端设备D之间的到达角(Direction of Arrival)以设计自身的波束成型器。Wherein, any of the distributed transmitting end devices S i (i=1, 2, K, N) and the receiving end device D are equipped with an omnidirectional single antenna, and the eavesdropping device E is equipped with a multi-antenna array to obtain more Channel direction information, thereby improving the eavesdropping capacity of the eavesdropping device E itself, for example by estimating the Direction of Arrival between the distributed transmitting device and the receiving device D to design its own beamformer.
在图1所示的分布式安全通信***中,发射端设备可以接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;进一步地,发射端设备可以根据所述反馈信号,调整第(n+1)时
隙发送第一人工噪声信号的发射权值的相关参数,以使所述第三人工噪声信号在所述接收端设备的干扰功率最小,从而可以提高分布式安全通信***的安全性。In the distributed secure communication system shown in FIG. 1, the transmitting end device may receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the receiving end device is in the first time slot of the nth time slot. Whether the noise ratio SINR is higher than the second SINR of the nth slot stored by the receiving end device; further, the transmitting end device may adjust the (n+1)th time according to the feedback signal.
The slot transmits a correlation parameter of the transmission weight of the first artificial noise signal to minimize the interference power of the third artificial noise signal at the receiving end device, thereby improving the security of the distributed secure communication system.
请参阅图2,图2是本发明实施例公开的一种基于反馈控制的分布式安全波束成型方法的流程示意图。其中,该基于反馈控制的分布式安全波束成型方法应用于分布式安全通信***包括的发射端设备,如图2所示,该基于反馈控制的分布式安全波束成型方法可以包括以下步骤:Please refer to FIG. 2. FIG. 2 is a schematic flowchart diagram of a distributed safety beamforming method based on feedback control according to an embodiment of the present invention. The distributed safety beamforming method based on feedback control is applied to a transmitting end device included in the distributed secure communication system. As shown in FIG. 2, the distributed safety beamforming method based on feedback control may include the following steps:
步骤201、发射端设备接收所述接收端设备发送的反馈信号。Step 201: The transmitting end device receives the feedback signal sent by the receiving end device.
其中,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升。所述第n时隙为当前时隙,所述n为正整数。The feedback signal is used to indicate whether the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device. The nth time slot is a current time slot, and the n is a positive integer.
作为一种可选的实施方式,在步骤201之前,发射端设备还可以在第n时隙向所述接收端设备发送携带有第二人工噪声信号的第一信号。其中,所述第二人工噪声信号用于干扰所述窃听端设备对第一信道方向信息的估计准确度。As an optional implementation manner, before the step 201, the transmitting end device may further send the first signal carrying the second artificial noise signal to the receiving end device in the nth time slot. The second artificial noise signal is used to interfere with the estimation accuracy of the first channel direction information by the eavesdropping device.
发射端设备在第n时隙向所述接收端设备发送携带有第二人工噪声信号的第一信号可以表示为:The transmitting, by the transmitting device, the first signal carrying the second artificial noise signal to the receiving device in the nth time slot may be expressed as:
其中,xC[n]表示第n个时隙内发送的保密信息,每一个分布式发射端设备在每个时隙内发送的保密信息是相同的,表示第i个分布式发射端设备发送保密信息的功率,表示第i个分布式发射端设备发送的第一人造噪声信号,它服从均值为0,方差为1的高斯分布,表示第i个发射端设备发送第二人造噪声的功率。其中,所有分布式发射端设备在每一个时隙内发送保密信息xC[n]的功率相同,发送第二人造噪声ξS,i[n]的功率相同,且它们满足如下条件:
Where x C [n] represents the secret information transmitted in the nth time slot, and the secret information transmitted by each distributed transmitting end device in each time slot is the same. Indicates the power of the i-th distributed transmitting device to send confidential information. Representing the first artificial noise signal transmitted by the ith distributed transmitting device, which obeys a Gaussian distribution with a mean of 0 and a variance of 1. Indicates that the i-th transmitting device transmits the second artificial noise Power. Among them, all distributed transmitting devices transmit the same power of the secret information x C [n] in each time slot, transmit the second artificial noise ξ S, i [n] have the same power, and they satisfy the following conditions:
其中PT表示每一个分布式发射端设备发送保密信息xC[n]与第二人造噪声ξS,i[n]功率之和的上限。表示第i个分布式发射端设备发送第二人造噪声ξS,i[n]的发射权值。当对每一个分布式发射端设备的发射相位进行优化时,该发射权值可表示为
Where P T represents the upper limit of the sum of the power of the secret information x C [n] and the second artificial noise ξ S, i [n] transmitted by each distributed transmitting device. Indicates the transmission weight of the second artificial transmitting device 发送S,i [n] transmitted by the ith distributed transmitting device. When the transmit phase of each distributed transmitting device is optimized, the transmit weight can be expressed as
其中,该发射权值的自适应组件即包括三个参数,发射相位修正因子以及随机扰动第i个发射端设备Si(i=1,2,K,N)生成的随机扰动其中,为扰动步长。初始化时,第i个发射端设备在第1个时隙时的最佳发射相位修正因子
Wherein, the transmission weight Adaptive component That includes three parameters, the emission phase Correction factor And random disturbance Random perturbation generated by the i-th transmitting device S i (i=1, 2, K, N) among them, To disturb the step size. Optimal transmission phase of the i-th transmitting device in the first time slot during initialization Correction factor
本发明的实施例中,所述接收端设备接收到多个发射端设备发送的第一信号之后,就可以根据该第一信号向发射端设备发送反馈信息,其中,第i个分布式发射端设备Si接收到的反馈信号可以表示为:In an embodiment of the present invention, after receiving the first signal sent by the multiple transmitting end devices, the receiving end device may send feedback information to the transmitting end device according to the first signal, where the ith distributed transmitting end The feedback signal received by device S i can be expressed as:
其中,xD[n]为接收端设备确定的反馈信号,PC2表示接收端设备D反馈单比特控制信息xB[n]的发射功率,Pξ2表示接收端设备D发射第二人工噪声信号ξD[n]的功率,ξD[n]~CN(0,1)。表示接收端设备D与第i个分布式发射端设备Si之间的未知相位,它服从[0,2π)间的均匀分布,表示接收端设备D与第i个分布式发射端设备Si之间反馈控制信息时信道的相位响应,表示第i个分布式发射端设备上的加性高斯白噪声。Where x D [n] is a feedback signal determined by the receiving device, P C2 indicates that the receiving device D feeds back the transmission power of the single bit control information x B [n], and P ξ 2 indicates that the receiving device D transmits the power of the second artificial noise signal ξ D [n], ξ D [n] to CN ( 0,1). Denote the unknown phase between the receiving device D and the ith distributed transmitting device S i , which obeys a uniform distribution between [0, 2π), Indicates the phase response of the channel when the control information is fed back between the receiving device D and the i-th distributed transmitting device S i , Represents additive white Gaussian noise on the ith distributed transmitter device.
步骤202、若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,发射端设备
确定
Step 202: If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, the transmitting end device determines
其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, A random perturbation of the transmission weight of the second artificial noise signal is transmitted for the nth time slot.
步骤203、发射端设备将所述发射端设备上的正反馈计数器的个数累加1。Step 203: The transmitting device adds 1 to the number of positive feedback counters on the transmitting device.
其中,第i个发射端设备Si(i=1,2,K,N)根据如下公式对其扰动步长进行更新:Wherein, the i-th transmitting end device S i (i=1, 2, K, N) is subjected to the disturbance step according to the following formula Update:
其中表示第i个发射端设备Si(i=1,2,K,N)上的正反馈计数器(在第1个时隙,初始值),可以将正确的随机扰动的个数记录下来,表示第i个发射端设备Si(i=1,2,K,N)对应于正反馈计数器的阈值。正确的随机扰动意味着所有发射端设备发射的人工噪声信号在接收端设备上的干扰功率下降。表示第i个发射端设备Si(i=1,2,K,N)上随机扰动步长的增长因子,在第1个时隙设定好后不再改变。第i个发射端设备Si(i=1,2,K,N)上的阈值按照如下规则进行更新:among them Indicates the positive feedback counter on the i-th transmitting device S i (i=1, 2, K, N) (in the first time slot, initial value ), You can record the number of correct random disturbances, Indicates that the i-th transmitting device S i (i=1, 2, K, N) corresponds to a positive feedback counter Threshold. Correct random perturbation means that the interference power of the artificial noise signal transmitted by all transmitting devices on the receiving device decreases. Indicates the random perturbation step size on the ith transmitter device S i (i=1, 2, K, N) The growth factor does not change after the first time slot is set. Threshold on the i-th transmitting device S i (i=1, 2, K, N) Update according to the following rules:
其中,表示第i个发射端设备Si(i=1,2,K,N)上阈值的修正因子,在第1个时隙设定好后不再改变,它可以通过修正阈值避免扰动步长过快增长。
among them, Indicates the threshold of the i-th transmitting device S i (i=1, 2, K, N) Correction factor, no change after the first time slot is set, it can pass the correction threshold Avoid disturbing steps Growing too fast.
步骤204、若累加后的正反馈计数器的个数大于或等于第一累加阈值,发射端设备确定
Step 204: If the number of accumulated positive feedback counters is greater than or equal to the first accumulated threshold, the transmitting device determines
其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为随机扰动步长的增长因子。among them, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Random disturbance step Growth factor.
其中,在所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,且累加后的正反馈计数器的个数大于或等于第一累加阈值的情况下,发射端设备才需要更新并确定反之,在所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,且累加后的正反馈计数器的个数小于第一累加阈值,发射端设备不需要更新并确定
The feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, and the accumulated positive feedback is performed. If the number of counters is greater than or equal to the first accumulated threshold, the transmitting device needs to update and determine Conversely, the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, and the accumulated positive feedback is performed. The number of counters is less than the first accumulated threshold, and the transmitting device does not need to update and determine
需要说明的是,对于正反馈计数器,是累加正反馈,如果两个正反馈之间出现了一个负反馈,打断了正反馈,正反馈计数器是不清0的。It should be noted that for the positive feedback counter, positive feedback is accumulated. If a negative feedback occurs between the two positive feedbacks, the positive feedback is interrupted, and the positive feedback counter is unclear.
步骤205、发射端设备保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,并结束本流程。Step 205: The transmitting device saves the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot, and ends the process.
本发明实施例中,在所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升的情况下,发射端设备需要保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,以为在第(n+1)时隙更新修正因子做准备。In the embodiment of the present invention, the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is higher than the second SINR of the nth slot stored by the receiving end device. The transmitting device needs to save the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot to prepare for updating the correction factor in the (n+1)th time slot.
步骤206、若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,发射端设备确定
Step 206: If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not higher than the second SINR of the nth slot stored by the receiving end device, the transmitting end device determines
步骤207、发射端设备将所述发射端设备上的负反馈计数器的个数累加1。
Step 207: The transmitting device adds 1 to the number of negative feedback counters on the transmitting device.
其中,为了所有发射端设备发射的人工噪声信号在接收端设备上的收敛准确度,需要适当的减小每一个发射端设备的扰动步长
Wherein, in order to achieve convergence accuracy of the artificial noise signal transmitted by all the transmitting end devices on the receiving end device, it is necessary to appropriately reduce the disturbance step size of each transmitting end device.
其中,第i个发射端设备Si(i=1,2,K,N)根据如下公式对其扰动步长进行更新:Wherein, the i-th transmitting end device S i (i=1, 2, K, N) is subjected to the disturbance step according to the following formula Update:
其中,表示第i个发射端设备Si(i=1,2,K,N)上的负反馈计数器(在第1个时隙的初始值),表示第i个发射端设备Si(i=1,2,K,N)对应于负反馈计数器的阈值,表示第i个分布式发射节点Si(i=1,2,K,N)上随机扰动步长的下降因子,在第1个时隙设定好后不再改变。当第i个发射端设备Si(i=1,2,K,N)的负反馈计数器达到其对应的阈值时,第i个发射端设备Si(i=1,2,K,N)的第二累加阈值将按照如下公式进行更新:among them, Indicates the negative feedback counter on the i-th transmitting device S i (i=1, 2, K, N) (initial value in the first slot) ), Indicates that the i-th transmitting device S i (i=1, 2, K, N) corresponds to a negative feedback counter Threshold, Represents the random perturbation step size on the i-th distributed transmitting node S i (i=1, 2, K, N) The drop factor does not change after the first time slot is set. Negative feedback counter for the i-th transmitter device S i (i=1, 2, K, N) Reach its corresponding threshold The second accumulated threshold of the i-th transmitting end device S i (i=1, 2, K, N) It will be updated as follows:
其中表示第i个分布式发射节点Si(i=1,2,K,N)上第二累加阈值的修正因子,在第1个时隙设定好后不再改变,它可以通过修正阈值来减小第i个发射端设备Si(i=1,2,K,N)上的随机扰动步长使得所有发射端设备协作发射的人工噪声信号在接收端设备上获得更好的收敛准确度。among them Representing the second accumulated threshold on the i-th distributed transmitting node S i (i=1, 2, K, N) Correction factor, no change after the first time slot is set, it can pass the correction threshold To reduce the random perturbation step size on the i-th transmitting end device S i (i=1, 2, K, N) The artificial noise signal that enables all the transmitting devices to cooperatively transmit achieves better convergence accuracy on the receiving device.
步骤208、若累加后的负反馈计数器的个数大于或等于第二累加阈值,发射端设备确定
Step 208: If the number of accumulated negative feedback counters is greater than or equal to the second accumulated threshold, the transmitting device determines
其中,在所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,且累加后的负反馈计数器的个数大于或等于第二累加阈值的情况下,发射端设备才需要更新并确定反之,在所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,且累加后的负反馈计数器的个数小于第二累加阈值的情况下,
发射端设备不需要更新并确定
The feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not increased compared to the second SINR of the nth slot stored by the receiving device, and the accumulated negative If the number of feedback counters is greater than or equal to the second accumulated threshold, the transmitting device needs to update and determine Conversely, the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is not increased compared to the second SINR of the nth slot stored by the receiving device, and the accumulated negative When the number of feedback counters is less than the second accumulated threshold, the transmitting device does not need to update and determine
需要说明的是,对于负反馈计数器,是连续负反馈,如果负反馈后被一个正反馈打断了,负反馈计数器要清0。It should be noted that for the negative feedback counter, it is continuous negative feedback. If the negative feedback is interrupted by a positive feedback, the negative feedback counter should be cleared to 0.
其中,实施图2所描述的方法,发射端设备可以接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;进一步地,发射端设备可以根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的发射相位、修正因子以及随机扰动,以使所述第三人工噪声信号在所述接收端设备的干扰功率最小,从而可以提高分布式安全通信***的安全性。The method described in FIG. 2, the transmitting end device may receive the feedback signal sent by the receiving end device, where the feedback signal is used to indicate the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot. Whether the second SINR of the nth time slot stored by the receiving end device is increased; further, the transmitting end device may adjust the (n+1)th time slot to send the first artificial noise signal according to the feedback signal. The transmit phase, the correction factor, and the random disturbance of the transmit weight are such that the interference power of the third artificial noise signal at the receiving device is minimized, thereby improving the security of the distributed secure communication system.
请参阅图3,图3是本发明实施例公开的另一种基于反馈控制的分布式安全波束成型方法的流程示意图。其中,该基于反馈控制的分布式安全波束成型方法应用于分布式安全通信***包括的接收端设备,如图3所示,该基于反馈控制的分布式安全波束成型方法可以包括以下步骤:Please refer to FIG. 3. FIG. 3 is a schematic flowchart diagram of another distributed safety beamforming method based on feedback control according to an embodiment of the present invention. The distributed safety beamforming method based on feedback control is applied to a receiving end device included in the distributed secure communication system. As shown in FIG. 3, the distributed safety beamforming method based on feedback control may include the following steps:
步骤301、接收端设备在第n时隙接收多个所述发射端设备发送的第一信号。Step 301: The receiving end device receives, in the nth time slot, a plurality of first signals sent by the transmitting end device.
其中,所述n为所述第n时隙为当前时隙,所述n为正整数。The n is the current time slot, and the n is a positive integer.
本发明实施例中,接收端设备在第n时隙接收多个所述发射端设备发送的第一信号,可以表示为In the embodiment of the present invention, the receiving end device receives, in the nth time slot, a plurality of first signals sent by the transmitting end device, which may be represented as
其中表示接收端D上的加性高斯白噪声(Additive White Gaussian Noise),表示第i个分布式发射节点Si与接收端D之间的未知相位,它服从[0,2π)间的均匀分布,表示第i个发射节点Si与接收端D之间第一阶段信道的相位响应。among them Indicates Additive White Gaussian Noise on the receiving end D, Representing the unknown phase between the ith distributed transmitting node S i and the receiving end D, which obeys a uniform distribution between [0, 2π), Indicates the phase response of the first phase channel between the i-th transmitting node S i and the receiving end D.
步骤302、接收端设备根据所述第一信号,确定在第n时隙的第一信干噪比SINR。
Step 302: The receiving end device determines, according to the first signal, a first signal to interference and noise ratio SINR in the nth time slot.
其中,接收端设备在第n时隙的信干噪比可表示为:The signal to interference and noise ratio of the receiving device in the nth time slot can be expressed as:
第n时隙发射端设备与接收端设备之间的互信息量RD[n]可以表示为:The amount of mutual information R D [n] between the transmitting device and the receiving device in the nth time slot can be expressed as:
RD[n]=log2(1+SINRD[n])R D [n]=log 2 (1+SINR D [n])
接收端设备D上的安全容量RS[n]可以表示为:The safety capacity R S [n] on the receiving device D can be expressed as:
RS[n]=[RD[n]-RE[n]]+
R S [n]=[R D [n]-R E [n]] +
其中,[x]+□max{0,x},即保证接收端设备D上可实现的安全容量RS≥0。Where [x] + □max{0, x}, that is, the safe capacity R S ≥ 0 achievable on the receiving device D is guaranteed.
步骤303、接收端设备根据所述第一SINR,确定反馈信号。Step 303: The receiving end device determines a feedback signal according to the first SINR.
其中,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;The feedback signal is used to indicate whether the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device;
所述接收端设备根据所述第一SINR,确定反馈信号包括:Determining, by the receiving device, the feedback signal according to the first SINR includes:
将所述第一SINR与所述第二SINR进行比较;Comparing the first SINR with the second SINR;
若所述第一SINR大于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR提升的反馈信号;If the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
若所述第一SINR小于或等于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR未提升的反馈信号。If the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
具体的,接收端设备确定的反馈信号可以表示为:Specifically, the feedback signal determined by the receiving device can be expressed as:
其中PC2表示接收端设备D反馈单比特控制信息xB[n]的发射功率,Pξ2表示接收端设备D发射第三人工噪声信号ξD[n]的功率,ξD[n]~CN(0,1)。Where P C2 indicates that the receiving device D feeds back the transmission power of the single bit control information x B [n], and P ξ 2 indicates that the receiving device D transmits the power of the third artificial noise signal ξ D [n], ξ D [n] ~ CN (0,1).
例如,可以用比特1表示所述第一SINR相较于所述第二SINR提升,并称其为单比特正反馈,用比特0表示所述第一SINR相较于所述第二SINR未提升,并称其为单比特负反馈。其中,接收端设备只需要反馈单比特控制信息,能够节省网络资源。For example, bit 1 may be used to indicate that the first SINR is compared to the second SINR, and is referred to as single-bit positive feedback, and bit 0 indicates that the first SINR is not improved compared to the second SINR. And call it a single-bit negative feedback. The receiving end device only needs to feed back single-bit control information, which can save network resources.
步骤304、接收端设备向多个所述发射端设备发送所述反馈信号。
Step 304: The receiving end device sends the feedback signal to a plurality of the transmitting end devices.
步骤305、接收端设备将所述第一SINR与所述第二SINR中较大的SINR存储为所述接收端设备第(n+1)时隙的SINR。Step 305: The receiving end device stores the larger SINR of the first SINR and the second SINR as the SINR of the (n+1)th slot of the receiving end device.
其中,所述第(n+1)时隙为所述当前时隙的下一个时隙。The (n+1)th time slot is the next time slot of the current time slot.
其中,实施图3所描述的方法,接收端设备可以在第n时隙接收多个所述发射端设备发送的第一信号;根据所述第一信号,确定在第n时隙的第一信干噪比SINR;以及根据所述第一SINR,确定反馈信号之后,向多个所述发射端设备发送所述反馈信号,这样,发射端设备就可以根据反馈信号调整第(n+1)时隙发送第一人工噪声信号的发射权值的发射相位、修正因子以及随机扰动,从而能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。The method described in FIG. 3, the receiving end device may receive the first signal sent by the multiple transmitting end devices in the nth time slot; and determine the first information in the nth time slot according to the first signal. a dry noise ratio SINR; and after determining the feedback signal according to the first SINR, transmitting the feedback signal to a plurality of the transmitting end devices, so that the transmitting end device can adjust the (n+1)th time according to the feedback signal The slot transmits the transmit phase, the correction factor, and the random disturbance of the transmit weight of the first artificial noise signal, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
请参阅图4,图4是本发明实施例公开的另一种基于反馈控制的分布式安全波束成型方法的流程示意图;其中,该基于反馈控制的分布式安全波束成型方法是从发射端设备以及接收端设备两侧来描述的,图4中的部分或全部步骤可以参照图2或图3中的描述,在此不再赘述。如图4所示,该基于反馈控制的分布式安全波束成型方法可以包括以下步骤:Referring to FIG. 4, FIG. 4 is a schematic flowchart diagram of another distributed safety beamforming method based on feedback control according to an embodiment of the present invention; wherein the distributed safety beamforming method based on feedback control is from a transmitting device and For some or all of the steps in FIG. 4, the description in FIG. 2 or FIG. 3 may be referred to, and details are not described herein again. As shown in FIG. 4, the feedback-based distributed safety beamforming method may include the following steps:
步骤401、发射端设备在第n时隙向接收端设备发送第一信号。Step 401: The transmitting end device sends the first signal to the receiving end device in the nth time slot.
步骤402、接收端设备根据所述第一信号,确定在第n时隙的第一信干噪比SINR。Step 402: The receiving end device determines, according to the first signal, a first signal to interference and noise ratio SINR in the nth time slot.
步骤403、接收端设备根据所述第一SINR,确定反馈信号。Step 403: The receiving end device determines a feedback signal according to the first SINR.
步骤404、接收端设备向多个所述发射端设备发送所述反馈信号。Step 404: The receiving end device sends the feedback signal to a plurality of the transmitting end devices.
步骤405、发射端设备根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的发射相位、修正因子以及随机扰动。Step 405: The transmitting end device adjusts, according to the feedback signal, a transmitting phase, a correction factor, and a random disturbance of transmitting the transmission weight of the first artificial noise signal in the (n+1)th time slot.
请一并参见图5,图5是本发明实施例公开的一种分布式安全通信***的保密容量的收敛示意图;如图5所示,分布式安全通信***的保密容量在迭代结束后明显提升,且发射端设备的个数越多,分布式安全通信***的保密容量越高。Referring to FIG. 5, FIG. 5 is a schematic diagram of convergence of a secure capacity of a distributed secure communication system according to an embodiment of the present invention; as shown in FIG. 5, the security capacity of the distributed secure communication system is significantly improved after the iteration ends. The more the number of transmitting devices, the higher the confidential capacity of the distributed secure communication system.
其中,实施图4所描述的基于反馈控制的分布式安全波束成型方法,发
射端设备可以在第n时隙向接收端设备发送第一信号,接收端设备根据所述第一信号,确定在第n时隙的第一信干噪比SINR,并根据所述第一SINR,确定反馈信号,并向多个所述发射端设备发送所述反馈信号,发射端设备就可以根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的发射相位、修正因子以及随机扰动,以使所述第三人工噪声信号在所述接收端设备的干扰功率最小,从而可以提高分布式安全通信***的安全性。Wherein, the distributed safety beamforming method based on feedback control described in FIG. 4 is implemented,
The transmitting device may send the first signal to the receiving device in the nth time slot, and the receiving device determines the first signal to interference and noise ratio SINR in the nth time slot according to the first signal, and according to the first SINR Determining a feedback signal and transmitting the feedback signal to a plurality of the transmitting end devices, and the transmitting end device may adjust the transmitting weight of the first artificial noise signal in the (n+1)th time slot according to the feedback signal. The transmission phase, the correction factor, and the random disturbance are such that the interference power of the third artificial noise signal at the receiving end device is minimized, thereby improving the security of the distributed secure communication system.
请参阅图6,图6是本发明实施例公开的一种分布式安全波束成型装置的结构示意图。其中,图6所描述的分布式安全波束成型装置可以行于分布式安全通信***包括的发射端设备,图6所描述的分布式安全波束成型装置可以用于执行图2或图4所描述的基于反馈控制的分布式安全波束成型方法中的部分或全部步骤,具体请参见图2或图4中的相关描述,在此不再赘述。如图6所示,该分布式安全波束成型装置可以包括:Please refer to FIG. 6. FIG. 6 is a schematic structural diagram of a distributed safety beamforming apparatus according to an embodiment of the present invention. Wherein, the distributed safety beamforming device described in FIG. 6 can be implemented in a transmitting end device included in the distributed secure communication system, and the distributed safety beam forming device described in FIG. 6 can be used to perform the description described in FIG. 2 or FIG. For some or all of the steps in the distributed safety beamforming method based on the feedback control, please refer to the related description in FIG. 2 or FIG. 4, and details are not described herein again. As shown in FIG. 6, the distributed safety beamforming device can include:
接收单元601,用于接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;The receiving unit 601 is configured to receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared with the receiving end device. Whether the second SINR of the stored nth slot is increased;
调整单元602,用于根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动;The adjusting unit 602 is configured to adjust, according to the feedback signal, a correlation parameter for transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;
其中,所述第n时隙为当前时隙,所述第(n+1)时隙为所述当前时隙的下一个时隙,所述n为正整数。The nth time slot is a current time slot, the (n+1)th time slot is a next time slot of the current time slot, and the n is a positive integer.
可选的,所述调整单元602包括:Optionally, the adjusting unit 602 includes:
第一确定子单元6021,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,确定
a first determining sub-unit 6021, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device ,determine
第二确定子单元6022,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,确定
a second determining sub-unit 6022, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is smaller than the second SINR of the nth slot stored by the receiving end device Upgrade, determine
其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,为随机扰动步长的增长因子,为随机扰动步长的下降因子。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, Transmitting a random perturbation of the transmission weight of the second artificial noise signal for the nth time slot, Random disturbance step Growth factor, Random disturbance step Declining factor.
可选的,所述分布式安全波束成型装置还包括:Optionally, the distributed safety beamforming device further includes:
第一计数单元603,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,将所述发射端设备上的正反馈计数器的个数累加1;a first counting unit 603, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, Adding the number of positive feedback counters on the transmitting device to 1;
若累加后的正反馈计数器的个数大于或等于第一累加阈值,确定
If the number of accumulated positive feedback counters is greater than or equal to the first accumulated threshold, determine
可选的,所述分布式安全波束成型装置还包括:Optionally, the distributed safety beamforming device further includes:
第二计数单元604,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,将所述发射端设备上的负反馈计数器的个数累加1;The second counting unit 604 is configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not improved compared to the second SINR of the nth time slot stored by the receiving end device Adding the number of negative feedback counters on the transmitting device to 1;
若累加后的负反馈计数器的个数大于或等于第二累加阈值,则执行所述
的确定
If the number of accumulated negative feedback counters is greater than or equal to the second accumulated threshold, then the determination is performed
可选的,所述分布式安全波束成型装置还包括:Optionally, the distributed safety beamforming device further includes:
保存单元605,用于保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。The saving unit 605 is configured to save the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot.
在图6所述的分布式安全波束成型装置中,发射端设备可以接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;进一步地,发射端设备可以根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动。可见,实施本发明实施例,发射端设备只需要使用接收端设备发送的反馈信息,就可以对第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数进行调整,以使所述第一人工噪声信号在所述接收端设备的干扰功率最小,从而能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。In the distributed safety beamforming apparatus of FIG. 6, the transmitting end device may receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate the first letter of the receiving end device in the nth time slot. Whether the dry-noise ratio SINR is higher than the second SINR of the n-th slot stored by the receiving device; further, the transmitting device may adjust the (n+1)th slot to send the first according to the feedback signal. A correlation parameter of a transmission weight of the artificial noise signal, the correlation parameter including a transmission phase, a correction factor, and a random disturbance. It can be seen that, in the embodiment of the present invention, the transmitting end device only needs to use the feedback information sent by the receiving end device, and can adjust the relevant parameters of the transmitting weight of the first artificial noise signal in the (n+1)th time slot to The interference power of the first artificial noise signal at the receiving end device is minimized, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
请参阅图7,图7是本发明实施例公开的另一种分布式安全波束成型装置的结构示意图。其中,图7所描述的分布式安全波束成型装置运行于分布式安全通信***包括的接收端设备,图7所描述的分布式安全波束成型装置可以用于执行图3或图4所描述的基于反馈控制的分布式安全波束成型方法中的部分或全部步骤,具体请参见图3或图4中的相关描述,在此不再赘述。如图7所示,该分布式安全波束成型装置可以包括:Please refer to FIG. 7. FIG. 7 is a schematic structural diagram of another distributed safety beamforming apparatus according to an embodiment of the present invention. Wherein, the distributed safety beamforming device described in FIG. 7 operates on a receiving end device included in the distributed secure communication system, and the distributed safety beamforming device described in FIG. 7 can be used to perform the method described in FIG. 3 or FIG. For some or all of the steps of the feedback-controlled distributed safety beamforming method, please refer to the related description in FIG. 3 or FIG. 4, and details are not described herein again. As shown in FIG. 7, the distributed safety beamforming device can include:
发送单元701,用于在第n时隙接收多个所述发射端设备发送的第一信号;其中,所述n为所述第n时隙为当前时隙,所述n为正整数。The sending unit 701 is configured to receive, by the nth time slot, a plurality of first signals sent by the transmitting end device, where n is the nth time slot is a current time slot, and the n is a positive integer.
第一确定单元702,用于根据所述第一信号,确定在第n时隙的第一信
干噪比SINR;a first determining unit 702, configured to determine, according to the first signal, a first letter in an nth time slot
Dry noise ratio SINR;
第二确定单元703,用于根据所述第一SINR,确定反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;a second determining unit 703, configured to determine, according to the first SINR, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the receiving Whether the second SINR of the nth slot stored by the end device is increased;
所述发送单元701,还用于向多个所述发射端设备发送所述反馈信号。The sending unit 701 is further configured to send the feedback signal to multiple sending end devices.
可选的,所述第二确定单元703根据所述第一SINR,确定反馈信号包括:Optionally, the determining, by the second determining unit 703, the feedback signal according to the first SINR includes:
将所述第一SINR与所述第二SINR进行比较;Comparing the first SINR with the second SINR;
若所述第一SINR大于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR提升的反馈信号;If the first SINR is greater than the second SINR, determining a feedback signal for indicating that the first SINR is compared to the second SINR;
若所述第一SINR小于或等于所述第二SINR,则确定用于表示所述第一SINR相较于所述第二SINR未提升的反馈信号。If the first SINR is less than or equal to the second SINR, determining a feedback signal indicating that the first SINR is not boosted compared to the second SINR.
可选的,所述分布式安全波束成型装置还包括:Optionally, the distributed safety beamforming device further includes:
存储单元704,用于将所述第一SINR与所述第二SINR中较大的SINR存储为所述接收端设备第(n+1)时隙的SINR;其中,所述第(n+1)时隙为所述当前时隙的下一个时隙。The storage unit 704 is configured to store the SINR of the first SINR and the second SINR as the SINR of the (n+1)th slot of the receiving end device; where the (n+1) The time slot is the next time slot of the current time slot.
在图7所描述的分布式安全波束成型装置中,接收端设备可以在第n时隙接收多个所述发射端设备发送的第一信号;根据所述第一信号,确定在第n时隙的第一信干噪比SINR;以及根据所述第一SINR,确定反馈信号之后,向多个所述发射端设备发送所述反馈信号,这样,发射端设备就可以根据反馈信号调整第(n+1)时隙发送第一人工噪声信号的发射权值的发射相位、修正因子以及随机扰动,从而能够实现分布式安全通信,同时,提高分布式安全通信***的保密性能。In the distributed safety beamforming apparatus described in FIG. 7, the receiving end device may receive the first signal sent by the plurality of transmitting end devices in the nth time slot; and determine the nth time slot according to the first signal. The first signal to interference and noise ratio SINR; and after determining the feedback signal according to the first SINR, sending the feedback signal to a plurality of the transmitting end devices, so that the transmitting end device can adjust the first according to the feedback signal. +1) The time slot transmits the transmission phase, the correction factor and the random disturbance of the transmission weight of the first artificial noise signal, thereby enabling distributed secure communication and improving the security performance of the distributed secure communication system.
在上述实施例中,对各个实施例的描述都各有侧重,某个实施例中没有详述的部分,可以参见其他实施例的相关描述。In the above embodiments, the descriptions of the various embodiments are different, and the details that are not detailed in a certain embodiment can be referred to the related descriptions of other embodiments.
在本申请所提供的几个实施例中,应该理解到,所揭露的装置,可通过
其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如所述单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个***,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性或其它的形式。In several embodiments provided by the present application, it should be understood that the disclosed device can be
Other ways to achieve. For example, the device embodiments described above are merely illustrative. For example, the division of the unit is only a logical function division. In actual implementation, there may be another division manner, for example, multiple units or components may be combined or may be Integrate into another system, or some features can be ignored or not executed. In addition, the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be electrical or otherwise.
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。The units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
另外,在本发明各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。上述集成的单元既可以采用硬件的形式实现,也可以采用软件功能单元的形式实现。In addition, each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit. The above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
所述集成的单元如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储器中。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的全部或部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储器中,包括若干指令用以使得一台计算机设备(可为个人计算机、服务器或者网络设备等)执行本发明各个实施例所述方法的全部或部分步骤。而前述的存储器包括:U盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、移动硬盘、磁碟或者光盘等各种可以存储程序代码的介质。The integrated unit, if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable memory. Based on such understanding, the technical solution of the present invention may contribute to the prior art or all or part of the technical solution may be embodied in the form of a software product stored in a memory. A number of instructions are included to cause a computer device (which may be a personal computer, server or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention. The foregoing memory includes: a U disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a removable hard disk, a magnetic disk, or an optical disk, and the like, which can store program codes.
本领域普通技术人员可以理解上述实施例的各种方法中的全部或部分步骤是可以通过程序来指令相关的硬件来完成,该程序可以存储于一计算机可读存储器中,存储器可以包括:闪存盘、只读存储器(英文:Read-Only Memory,简称:ROM)、随机存取器(英文:Random Access Memory,简称:RAM)、磁盘或光盘等。
A person skilled in the art can understand that all or part of the steps of the foregoing embodiments can be completed by a program to instruct related hardware, and the program can be stored in a computer readable memory, and the memory can include: a flash drive , read-only memory (English: Read-Only Memory, referred to as: ROM), random accessor (English: Random Access Memory, referred to as: RAM), disk or CD.
以上对本发明实施例公开的一种基于反馈控制的分布式安全波束成型方法及装置进行了详细介绍,本文中应用了具体个例对本发明的原理及实施方式进行了阐述,以上实施例的说明只是用于帮助理解本发明的方法及其核心思想;同时,对于本领域的一般技术人员,依据本发明的思想,在具体实施方式及应用范围上均会有改变之处,综上所述,本说明书内容不应理解为对本发明的限制。
The method and device for distributed safety beamforming based on feedback control disclosed in the embodiment of the present invention are described in detail. The principle and implementation manner of the present invention are described in the following. The description of the above embodiment is only The method for understanding the present invention and its core idea; at the same time, for those of ordinary skill in the art, according to the idea of the present invention, there will be changes in specific embodiments and application scopes. The description should not be construed as limiting the invention.
Claims (10)
- 一种基于反馈控制的分布式安全波束成型方法,其特征在于,应用于分布式安全通信***包括的发射端设备,所述分布式安全通信***包括多个所述发射端设备、接收端设备以及窃听端设备,所述方法包括:A distributed safety beamforming method based on feedback control is characterized in that it is applied to a transmitting end device included in a distributed secure communication system, and the distributed secure communication system includes a plurality of the transmitting end device and a receiving end device, and The eavesdropping device, the method comprising:接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;Receiving, by the receiving end device, a feedback signal, where the feedback signal is used to indicate that the first signal to interference and noise ratio SINR of the receiving end device in the nth time slot is compared to the nth time slot stored by the receiving end device Whether the second SINR is increased;根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动;And adjusting, according to the feedback signal, a correlation parameter of transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;其中,所述第n时隙为当前时隙,所述第(n+1)时隙为所述当前时隙的下一个时隙,所述n为正整数。The nth time slot is a current time slot, the (n+1)th time slot is a next time slot of the current time slot, and the n is a positive integer.
- 根据权利要求1所述的方法,其特征在于,所述根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数包括:The method according to claim 1, wherein the adjusting related parameters of transmitting the transmission weight of the first artificial noise signal in the (n+1)th time slot according to the feedback signal comprises:若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,确定 If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determining若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,确定 If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, determining其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,为 随机扰动步长的增长因子,为随机扰动步长的下降因子。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, Transmitting a random perturbation of the transmission weight of the second artificial noise signal for the nth time slot, Random disturbance step Growth factor, Random disturbance step Declining factor.
- 根据权利要求2所述的方法,其特征在于,所述方法还包括:The method of claim 2, wherein the method further comprises:若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,将所述发射端设备上的正反馈计数器的个数累加1;If the feedback signal is used to indicate that the first SINR of the receiving device in the nth slot is higher than the second SINR of the nth slot stored by the receiving device, the device on the transmitting device The number of positive feedback counters is incremented by one;
- 根据权利要求2所述的方法,其特征在于,所述方法还包括:The method of claim 2, wherein the method further comprises:若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,将所述发射端设备上的负反馈计数器的个数累加1;If the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, the transmitting end device is The number of negative feedback counters is incremented by one;
- 根据权利要求3所述的方法,其特征在于,所述方法还包括:The method of claim 3, wherein the method further comprises:保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。And storing the random perturbation of the transmission weight of the second artificial noise signal in the nth time slot.
- 一种分布式安全波束成型装置,其特征在于,运行于分布式安全通信***包括的发射端设备,包括:A distributed safety beamforming device, characterized in that: the transmitting device included in the distributed secure communication system comprises:接收单元,用于接收所述接收端设备发送的反馈信号,所述反馈信号用于表示所述接收端设备在第n时隙的第一信干噪比SINR相较于所述接收端设备存储的第n时隙的第二SINR是否提升;a receiving unit, configured to receive a feedback signal sent by the receiving end device, where the feedback signal is used to indicate that the first signal to interference and noise ratio (SINR) of the receiving end device in the nth time slot is compared with the receiving end device. Whether the second SINR of the nth time slot is increased;调整单元,用于根据所述反馈信号,调整第(n+1)时隙发送第一人工噪声信号的发射权值的相关参数,所述相关参数包括发射相位、修正因子以及随机扰动;And an adjusting unit, configured to adjust, according to the feedback signal, a correlation parameter for transmitting a transmission weight of the first artificial noise signal in the (n+1)th time slot, where the correlation parameter includes a transmission phase, a correction factor, and a random disturbance;其中,所述第n时隙为当前时隙,所述第(n+1)时隙为所述当前时隙 的下一个时隙,所述n为正整数。The nth time slot is a current time slot, and the (n+1)th time slot is the current time slot. The next time slot, the n is a positive integer.
- 根据权利要求6所述的分布式安全波束成型装置,其特征在于,所述调整单元包括:The distributed safety beamforming device according to claim 6, wherein the adjustment unit comprises:第一确定子单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,确定 a first determining subunit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is higher than the second SINR of the nth time slot stored by the receiving end device, determine第二确定子单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,确定 a second determining subunit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not improved compared to the second SINR of the nth time slot stored by the receiving end device ,determine其中,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的发射相位,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的修正因子,为第(n+1)时隙发送所述第一人工噪声信号的发射权值的随机扰动,为第n时隙发送第二人工噪声信号的发射权值的发射相位,为第n时隙发送所述第二人工噪声信号的发射权值的修正因子,为第n时隙发送所述第二人工噪声信号的发射权值的随机扰动,为随机扰动步长的增长因子,为随机扰动步长的下降因子。among them, Transmitting a transmission phase of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a correction factor of a transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a random perturbation of the transmission weight of the first artificial noise signal for the (n+1)th time slot, Transmitting a transmission phase of a transmission weight of the second artificial noise signal for the nth time slot, Transmitting a correction factor for the transmission weight of the second artificial noise signal for the nth time slot, Transmitting a random perturbation of the transmission weight of the second artificial noise signal for the nth time slot, Random disturbance step Growth factor, Random disturbance step Declining factor.
- 根据权利要求7所述的分布式安全波束成型装置,其特征在于,所述分布式安全波束成型装置还包括:The distributed safety beamforming apparatus according to claim 7, wherein the distributed safety beamforming apparatus further comprises:第一计数单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR提升,将所述发射端设备上的正反馈计数器的个数累加1;a first counting unit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth slot is higher than the second SINR of the nth slot stored by the receiving device, The number of positive feedback counters on the transmitting device is accumulated by one;
- 根据权利要求8所述的分布式安全波束成型装置,其特征在于,所述分布式安全波束成型装置还包括:The distributed safety beamforming apparatus according to claim 8, wherein the distributed safety beamforming apparatus further comprises:第二计数单元,用于若所述反馈信号用于表示所述接收端设备在第n时隙的第一SINR相较于所述接收端设备存储的第n时隙的第二SINR未提升,将所述发射端设备上的负反馈计数器的个数累加1;a second counting unit, configured to: if the feedback signal is used to indicate that the first SINR of the receiving end device in the nth time slot is not increased compared to the second SINR of the nth time slot stored by the receiving end device, Adding the number of negative feedback counters on the transmitting device to 1;
- 根据权利要求9所述的分布式安全波束成型装置,其特征在于,所述分布式安全波束成型装置还包括:The distributed safety beamforming device according to claim 9, wherein the distributed safety beamforming device further comprises:保存单元,用于保存第n时隙发送所述第二人工噪声信号的发射权值的随机扰动。 And a saving unit, configured to save the random disturbance of transmitting the weight of the second artificial noise signal in the nth time slot.
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