FR3079985A1 - METHOD FOR AUTOMATICALLY ADJUSTING AN AGREEMENT UNIT, AND RADIO TRANSMITTER-RECEIVER USING THE SAME - Google Patents

Abstract

The invention relates to a method for automatically adjusting a tuning unit with multiple input access and multiple output access. The invention also relates to a radio transceiver using this method. A radio transceiver according to the invention comprises: 4 antennas (1 1) (12) (13) (14) which form a network of multiple access antennas (1); a multiple input and multiple output access tuning unit (4) having 4 input ports and 4 output ports; 4 detection units (31) (32) (33) (34); 4 antenna links (21) (22) (23) (24); a radio unit (8), the radio unit receiving, from a radio network, a radio signal providing an authorization to use, for excitations intended for adjustment, one or more data symbols, the radio unit applying 4 excitations at the input ports, one and only one of the excitations being applied to each of the input ports, the radio unit issuing tuning unit setting instructions; and a control unit (6), which supplies one or more tuning control signals to the tuning unit with multiple input access and multiple output access.   

Description

Method for automatic tuning of a tuning unit, and radio transceiver using this method

TECHNICAL FIELD OF THE INVENTION

The invention relates to a method for automatically adjusting a tuning unit with multiple input access and multiple output access of a radio transceiver using several antennas simultaneously to communicate in a radio network, the radio network being able for example to be a cellular radio network. The invention also relates to a radio transceiver using this method.

PRIOR STATE OF THE ART

In the following, in accordance with the “IEC multilingual dictionary of electricity” published by the Central Bureau of the International Electrotechnical Commission in 1983, “open loop control” (literal translation of the expression “open-loop control” of the language English), synonymous with “open chain command”, means a command that does not use a measurement of the quantity ordered, and “closed loop command” (literal translation of the expression “closed-loop control” from the English language), synonymous with “closed chain control” and “servo control”, means a command where the action on the controlled system is made dependent on a measurement of the quantity ordered.

Tuning an impedance matrix means obtaining that an impedance matrix presented by a plurality of input ports of a device is close to a desired impedance matrix, and simultaneously offering ideally lossless, or almost lossless power transfer, from the plurality of input ports to a plurality of device output ports, in a context where the impedance matrix seen by the plurality of output ports can vary. Thus, if the accesses of a multiple access signal generator having an impedance matrix equal to the assistant matrix (that is to say a matrix equal to the transposed matrix of the conjugate complex matrix) of the sought impedance matrix are suitably connected to the plurality of input ports, said multiple access signal generator supplies maximum power to the plurality of input ports, and the plurality of output ports supplies power close to this maximum power.

A multiple input and multiple output access tuning unit behaves, at any frequency in a given frequency band, with respect to its input and output ports, much like a passive linear device , where 'passive' is used in the sense of circuit theory. More precisely, a tuning unit with multiple input access and multiple output access behaves, at any frequency in a given frequency band, with respect to its n output ports and its m input ports, where n and m are non-harmful integers, much like a passive linear device with n + m access. As a consequence of linearity, it is possible to define the impedance matrix presented by the input ports. As a consequence of passivity, the multi-input and multiple-output access tuning unit does not provide amplification. A multiple input and multiple output access tuning unit has a plurality of adjustable impedance devices each having an adjustable reactance. Setting a multiple input and multiple output access tuning unit means adjusting the reactance of one or more of its impedance-adjustable devices. A multiple input and multiple output access tuning unit can be used to tune an impedance matrix. To tune an impedance matrix, the tuning unit with multiple input access and multiple output access must be properly set, that is, the reactances of its adjustable impedance devices must be properly set.

An adjustable impedance device is a component comprising two terminals which behave substantially like the terminals of a passive linear bipole, and which are therefore characterized by an impedance which may depend on the frequency, this impedance being adjustable.

An adjustable impedance device having an electrically adjustable reactance can be such that it provides only, at a given frequency, a finite set of reactance values, this characteristic being for example obtained if the adjustable impedance device is:

- a network comprising a plurality of capacitors or sections of transmission line in open circuit and one or more electrically controlled switches or switches, such as electromechanical relays, or microelectromechanical switches, or PIN diodes or field effect transistors insulated grid, used to make different capacitors or different sections of transmission line in open circuit of the network contribute to reactance; or

- a network comprising a plurality of coils or shortened transmission line sections and one or more electrically controlled switches or switches used to cause different coils or different shorted transmission line sections of the network to reactance .

An adjustable impedance device having an electrically adjustable reactance may be such that it provides, at a given frequency, a continuous set of reactance values, this characteristic being for example obtained if the adjustable impedance device is based on the use of a variable capacity diode; or a variable capacity MOS component (in English: "MOS varactor"); or a microelectromechanical component with variable capacity (in English: "MEMS varactor"); or a ferroelectric component with variable capacity (in English: “ferroelectric varactor”).

U.S. Patent No. 9,077,317, entitled “Method and apparatus for automatically tuning an impedance matrix, and radio transmitter using this apparatus”, discloses a first method for automatically tuning an impedance matrix, this method using at least m different excitations applied successively to the entry ports. Unfortunately, this method is usually not compatible with the specification of a radio transmitter used for radio communications ΜΙΜΟ, because the generation of a sequence of at least m different excitations applied successively results in a prolonged emission of electromagnetic waves. , which is not usually compatible with the requirements of all transmission modes ΜΙΜΟ of applicable standards, for example LTE-Advanced standards.

This problem is solved in a second method for automatically tuning an impedance matrix, disclosed in international application number PCT / IB2015 / 057131 of 16 September 2015 (WO 2016/207705), in which the excitations do not have to be applied successively.

A block diagram of a system implementing the first method for automatically tuning an impedance matrix, or the second method for automatically tuning an impedance matrix, is shown in Figure 1. This system is part of an apparatus for communication radio. The system shown in Figure 1 am = 4 user ports (311) (321) (331) (341), the m user ports having, at a given frequency, an impedance matrix called “the impedance matrix presented by user accesses” , the system comprising:

n = 4 antennas (11) (12) (13) (14), the n antennas operating simultaneously in a given frequency band, the n antennas forming an array of multiple access antennas (1);

m detection units (31) (32) (33) (34), each of the detection units delivering two “detection unit output signals”, each of the detection unit output signals being determined by a variable electrical sensed (or measured) at one of the user ports;

a multiple input and multiple output access tuning unit (4) having m input access and n output access, each of the input accesses being coupled to one and only one of the user accesses through a and only one of the detection units, the tuning unit with multiple input access and multiple output access comprising p devices with adjustable impedance, where p is an integer greater than or equal to m, the p devices with adjustable impedance being called the “adjustable impedance devices of the tuning unit” and being such that, at said given frequency, each of the adjustable impedance devices of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being electrically adjustable;

n antenna links (21) (22) (23) (24), each of the antenna links having a first end coupled to a signal access of one and only one of the antennas, each of the antenna links having a second end coupled to one and only one of the outlet ports;

a signal processing unit (5), the signal processing unit estimating q real quantities dependent on the impedance matrix presented by the user ports, where q is an integer greater than or equal to m, using the output signals d the detection unit caused by m excitations applied to the user ports, the signal processing unit delivering a “setting instruction” as a function of said q real quantities dependent on the impedance matrix presented by the user ports; and a control unit (6), the control unit receiving the adjustment instruction from the signal processing unit (5), the control unit delivering "control signals", the control signals being determined according to the adjustment instruction, the reactance of each of the adjustable impedance devices of the tuning unit being mainly determined by at least one of the control signals.

The first method for automatically tuning an impedance matrix and the second method for automatically tuning an impedance matrix are based on closed loop control, and do not include the description of a fast control technique, so that a setting automatic full tuning unit with multiple input access and multiple output access requires several iterations, each iteration comprising the following steps: applying m excitations to m user accesses; estimate q real quantities dependent on the impedance matrix presented by the user ports; issue a setting instruction; and deliver control signals. To be compatible with the requirements of the standards typically applicable to radio networks ΜΙΜΟ, each iteration must typically use, for the excitations, one or more data symbols (for example an OFDMA or SC-FDMA data symbol) comprising elementary resources (in English “resource clements”) allocated to reference signals (also called pilot signals) for the estimation of the channel ΜΙΜΟ. This has two undesirable consequences: first, the pilot signals of a data symbol used in an iteration give an incorrect estimate of the channel ΜΙΜΟ, since the channel is modified at the end of the iteration; and secondly, said complete automatic adjustment is very slow, because the reference signals are not very frequent.

This problem is solved in a third method for automatically tuning an impedance matrix, disclosed in the international application number PCTÆB2015 / 057161 of September 17, 2015 (WO 2017/033048). A block diagram of a system implementing the third method for automatically tuning an impedance matrix is shown in Figure 2. This system is part of an apparatus for radio communication. The system shown in Figure 2 am = 4 user ports (311) (321) (331) (341), the m user ports having, at a given frequency, an impedance matrix called “the impedance matrix presented by user accesses” , the system comprising:

n = 4 antennas (11) (12) (13) (14), the n antennas operating simultaneously in a given frequency band, the n antennas forming an array of multiple access antennas (1);

a multiple input and multiple output access tuning unit (4) having m input access and n output access, each of the input accesses being coupled to one and only one of the user accesses, the tuning unit with multiple input access and multiple output access comprising p devices with adjustable impedance, wherep is an integer greater than or equal to m, the p devices with adjustable impedance being called the “devices with adjustable impedance of the unit tuning ”and being such that, at said given frequency, each of the adjustable impedance devices of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being adjustable by electric means;

n detection units (31) (32) (33) (34), each of the detection units delivering two “detection unit output signals”, each of the detection unit output signals being determined by a variable electrical sensed (or measured) at one of the output ports;

n antenna links (21) (22) (23) (24), each of the antenna links having a first end which is directly coupled to a signal access from one and only one of the antennas, each of the antenna having a second end which is indirectly coupled to one and only one of the output ports, through one and only one of the detection units;

a signal processing unit (5), the signal processing unit estimating q real quantities dependent on an impedance matrix seen by the output ports, where q is an integer greater than or equal to m, using the signals of detection unit output caused by m excitations applied to user accesses, the signal processing unit delivering an “adjustment instruction” as a function of said q real quantities dependent on the impedance matrix seen by the output accesses; and a control unit (6), the control unit receiving the adjustment instruction from the signal processing unit (5), the control unit delivering "control signals", the control signals being determined according to the adjustment instruction, the reactance of each of the adjustable impedance devices of the tuning unit being mainly determined by at least one of the control signals.

The third method for automatically tuning an impedance matrix is based on open loop control, so it can be fast, but is typically imprecise. To be compatible with the requirements of the standards typically applicable to radio networks ΜΙΜΟ, the third method must typically use, for the excitations, a data symbol comprising elementary resources allocated to reference signals for the estimation of the channel ΜΙΜΟ. This has an undesirable consequence: the pilot signals of a data symbol used in the process give an incorrect estimate of the channel ΜΙΜΟ, since the channel is modified when the control signals are delivered.

Thus, the state of the prior art does not teach a precise and rapid process for automatically tuning an impedance matrix, and the state of the prior art does not teach a process compatible with the requirements of the standards typically applicable to radio networks ΜΙΜΟ, and which does not give an incorrect estimate of the channel ΜΙΜΟ.

STATEMENT OF THE INVENTION

The subject of the invention is a method for automatically adjusting a tuning unit with multiple input access and multiple output access, devoid of the above-mentioned limitations of known techniques, and also a radio transceiver using this method.

In the following, X and Y being different quantities or variables, performing an action as a function of X does not exclude the possibility of performing this action as a function of Y. In the following, “having an influence” and “having a effect ”have the same meaning. In the following, “coupled”, when this term is applied to two ports (in the sense of circuit theory), can indicate that the ports are directly coupled, each terminal of one of the ports being in this case connected to (or , equivalently, in electrical contact with) one and only one of the terminals of the other access, and / or that the accesses are indirectly coupled, an electrical interaction different from the direct coupling existing in this case between the accesses, for example at through one or more components.

The method according to the invention is a method for automatically adjusting a tuning unit with multiple input access and multiple output access, the tuning unit with multiple input access and multiple output access having m access d input and n output access, where m and n are each an integer greater than or equal to 2, the tuning unit with multiple input access and multiple output access comprising p devices with adjustable impedance, where p is a integer greater than or equal to m, the p devices with adjustable impedance being called the “devices with adjustable impedance of the tuning unit” and being such that, at a given frequency, each of the devices with adjustable impedance of the unit d tuning to a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being electrically adjustable, the reactance of any of the devices to i The adjustable tuning unit's pedance being primarily determined by at least one tuning control signal, the multi-input and multiple output access tuning unit being part of a radio transceiver comprising N antennas used to communicate in a radio network, where N is an integer greater than or equal to 2, the radio transceiver allowing, at the given frequency, a transfer of power from the m input accesses to a electromagnetic field radiated by the antennas, the method comprising the following steps:

receive, from the radio network, a radio signal providing an authorization to use, for excitations intended for adjustment, one or more data symbols, each of said data symbols being called "authorized data symbol";

applying m excitations to the m entry ports, one and only one of the excitations being applied to each of the entry ports, the excitations existing inside one or more of the one or more authorized data symbols;

pick up one or more electrical variables at each of the input ports, to obtain “detection unit output signals”, each of the detection unit output signals being mainly determined by at least one of the electrical variables picked up at one of the entrance entrances;

estimate q real quantities dependent on the impedance matrix presented by the input ports, where q is an integer greater than or equal to m, using the output signals from the detection unit;

use the said q real quantities dependent on the impedance matrix presented by the input ports, to obtain the one or more tuning control signals.

The method according to the invention may for example be such that a radio transceiver requests the radio network for authorization to use, for excitations intended for adjustment, one or more data symbols; and then the radio transceiver receives said authorization. In this case, the method can for example be such that the radio transceiver specifies the one or more data symbols that it requests to use.

The method according to the invention can for example be such that the radio network specifies the one or more authorized data symbols.

The method according to the invention may for example be such that the excitations exist only within one or more elementary resources of the one or more authorized data symbols.

The given frequency can for example be a frequency greater than or equal to 150 MHz. The specialist understands that an impedance matrix seen by the output ports is a square complex matrix of order n, and that an impedance matrix presented by the input ports is a square complex matrix of order m. We will use Z _{5an /} to designate the impedance matrix seen by the output _ports , and Z _; to designate the impedance matrix presented by the input ports. Each of these matrices depends on the frequency. also depends on the one or more tuning control signals, so that the method according to the invention uses closed loop control.

Each of the N antennas has an access, called "signal access" to the antenna, which can be used to receive and / or emit electromagnetic waves. It is assumed that each of the antennas behaves, at the given frequency, with respect to the signal access of the antenna, substantially like a passive antenna, that is to say like an antenna which is linear and which does not do not use an amplifier to amplify signals received by the antenna or transmitted by the antenna. As a consequence of the linearity, it is possible to define an impedance matrix presented by the antennas, the definition of which considers, for each of the antennas, only the signal access of the antenna. This matrix is therefore a square matrix of order N. Because of the interactions between the antennas, this matrix is not necessarily diagonal. In particular, the invention can be such that this matrix is not a diagonal matrix.

It is said above that the radio transceiver allows, at the given frequency, a transfer of power from the m input ports to an electromagnetic field radiated by the antennas. In other words, the radio transceiver is such that, if power is received by the m input ports at the given frequency, part of said power received by the m input ports is transferred to a electromagnetic field radiated by the antennas at the given frequency, so that a power of the electromagnetic field radiated by the antennas at the given frequency is equal to said part of said power received by the m input ports. For example, the specialist knows that a power of the electromagnetic field radiated by the antennas (average radiated power) can be calculated as the flux of the real part of a complex Poynting vector of the electromagnetic field radiated by the antennas, through a closed surface containing the antennas.

To obtain that the radio transceiver allows, at the given frequency, a transfer of power from the m input ports to an electromagnetic field radiated by the antennas, each of the antennas can, if n = N, for example be coupled, directly or indirectly, to one and only one of the output ports, as explained below in the presentation of the first embodiment. More precisely, if n = N, for each of the antennas, the signal access of the antenna can for example be coupled, directly or indirectly, to one and only one of the output ports. For example, an indirect coupling can be a coupling through an antenna link. For suitable values of the one or more tuning control signals, said power transfer from the m input ports to an electromagnetic field radiated by the antennas can for example be a power transfer with low or negligible losses. or miles, this characteristic being preferred.

The method according to the invention can for example be such that any diagonal element of the impedance matrix presented by the input ports is influenced by the reactance of at least one of the devices with adjustable impedance of the tuning unit. The method according to the invention can for example be such that the reactance of at least one of the devices with adjustable impedance of the tuning unit has an influence on at least one non-diagonal element of the impedance matrix presented by the accesses of 'Entrance.

An apparatus implementing the method according to the invention is a radio transceiver for communicating in a radio network comprising:

N antennas, where N is an integer greater than or equal to 2;

a tuning unit with multiple input access and multiple output access having m input access and n output access, where m and n are each an integer greater than or equal to 2, the radio transceiver allowing, at a given frequency, a transfer of power from the m input ports to an electromagnetic field radiated by the antennas, the tuning unit with multiple input ports and multiple output ports comprising p devices with adjustable impedance , where p is an integer greater than or equal to m, the p devices with adjustable impedance being called the “devices with adjustable impedance of the tuning unit” and being such that, at the given frequency, each of the devices with adjustable impedance of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being electrically adjustable;

m detection units, each of the detection units delivering one or more “detection unit output signals”, each of the detection unit output signals being mainly determined by one or more electrical variables picked up at one of the accesses d 'Entrance ;

a radio unit, the radio unit receiving, from the radio network, a radio signal providing an authorization to use, for excitations intended for adjustment, one or more data symbols, each of said data symbols being called “symbol of data authorized ”, the radio unit applying m excitations to the m entry ports, one and only one of the excitations being applied to each of the entry ports, the excitations existing inside one or more of the one or more authorized data symbols, the radio unit estimating q real quantities dependent on the impedance matrix presented by the input ports, where q is an integer greater than or equal to m, using the output signals of the detection unit, l radio unit delivering one or more “tuning unit setting instructions”, at least one of the one or more tuning unit setting instructions being determined in function tion of q real quantities dependent on the impedance matrix presented by the input ports; and a control unit, the control unit receiving the tuning unit setting instructions, the control unit delivering one or more “tuning control signals” to the access tuning unit. 'multiple input and multiple output access, each of the tuning control signals being determined based on at least one of the tuning unit setting instructions, the reactance of each of the unit's adjustable impedance devices being mainly determined by at least one of the one or more tuning control signals.

For example, each of said electrical variables can be a voltage, or an incident voltage, or a reflected voltage, or a current, or an incident current, or a reflected current.

As explained above, if n = N, it is for example possible that each of the antennas is coupled, directly or indirectly, to one and only one of the output ports. As explained above, if n = N, it is for example possible that, for each of the antennas, the signal access of the antenna is coupled, directly or indirectly, to one and only one of the output ports. Thus, said power transfer (from the m input ports to an electromagnetic field radiated by the antennas) can occur through the multiple input access and multiple output access tuning unit. The entire can be greater than or equal to 2m.

It is for example possible that each of the m input ports is coupled, directly or indirectly, to an access from the radio unit, said access from the radio unit delivering one and only one of the excitations.

For example, it is possible that the reactance of any of the tuned unit's impedance devices may influence an impedance matrix presented by the input ports.

The specialist understands that the radio transceiver according to the invention is adaptive in the sense that the reactances of the devices with adjustable impedance of the tuning unit are modified over time as a function of the output signals of the tuning unit. detection, which are each mainly determined by one or more electrical variables. The radio transceiver according to the invention uses closed loop control.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and characteristics will emerge more clearly from the description which follows of particular embodiments of the invention, given by way of nonlimiting examples, and represented in the appended drawings in which:

FIG. 1 represents a block diagram of an automatic adjustment system, and has already been commented on in the section devoted to the presentation of the state of the art;

FIG. 2 represents a block diagram of an automatic adjustment system, and has already been commented on in the section devoted to the presentation of the state of the art;

FIG. 3 represents a block diagram of a radio transceiver according to the invention.

DETAILED PRESENTATION OF CERTAIN EMBODIMENTS

First embodiment.

As a first embodiment of a device according to the invention, given by way of nonlimiting example, we have shown in FIG. 3 the block diagram of a radio transceiver for communicating in a radio network comprising :

2V = 4 antennas (11) (12) (13) (14), the antennas operating simultaneously in a given frequency band, the antennas forming an array of multiple access antennas (1);

a multiple input access and multiple output access tuning unit (4) having m = 4 input access and n = N output access, the multiple input access and access port tuning unit multiple output comprising p devices with adjustable impedance, where p is an integer greater than or equal to 2m = 8, lesp devices with adjustable impedance being called “devices with adjustable impedance of the tuning unit” and being such that, at a given frequency greater than or equal to 300 MHz, each of the adjustable impedance devices of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being adjustable by electrical means ;

m detection units (31) (32) (33) (34), each of the detection units delivering two “detection unit output signals”, each of the detection unit output signals being determined by a variable electrical sensed (or measured) at one of the input ports;

TV antenna links (21) (22) (23) (24), each of the antenna links having a first end which is directly coupled to a signal access of one and only one of the antennas, each of the antenna having a second end which is directly coupled to one and only one of the output ports;

a radio unit (8), the radio unit receiving, from the radio network, a radio signal providing an authorization to use, for excitations intended for an internal adjustment of the radio transceiver, one or more data symbols, each of said data symbols being called “authorized data symbol”, the radio unit applying m excitations to m input ports, one and only one of the excitations being applied to each of the input ports, the excitations existing at l inside one or more of the one or more authorized data symbols, the radio unit estimating q real quantities dependent on the impedance matrix presented by the input ports, where q is an integer greater than or equal to m, using the detection unit output signals, the radio unit delivering one or more “tuning unit setting instructions”, at least one of the one or more tuning setting instructions tuning unit being determined based on q dependent real quantities of the impedance matrix presented by the input port; and a control unit (6), the control unit receiving the tuning unit setting instructions, the control unit supplying one or more “tuning control signals” to the tuning unit with multiple input access and multiple output access, each of the tuning control signals being determined as a function of at least one of the tuning unit setting instructions, the reactance of each of the impedance adjustable devices of the tuning unit being mainly determined by at least one of the one or more tuning control signals.

Each of the antennas is coupled to one and only one of the output ports. More precisely, for each of the antennas, the signal access of the antenna is indirectly coupled to one and only one of the output ports, through one and only one of the antenna links. In addition, each of the output ports is coupled to one and only one of the antennas. More precisely, each of the output ports is indirectly coupled to the signal access of one and only one of the antennas, through one and only one of the antenna links. The given frequency is in the given frequency band. The given frequency band contains only frequencies greater than or equal to 300 MHz.

Each of the detection units (31) (32) (33) (34) may for example be such that the two detection unit output signals delivered by said each of the detection units comprise: a first output signal of detection unit proportional to a first electrical variable, the first electrical variable being a voltage across one of the input ports; and a second detection unit output signal proportional to a second electrical variable, the second electrical variable being a current entering said one of the input ports. Said voltage across one of the input ports may be a complex voltage and said current entering said one of the input ports may be a complex current. Alternatively, each of the detection units (31) (32) (33) (34) may for example be such that the two detection unit output signals delivered by said each of the detection units comprise: a first output signal detection unit proportional to a first electrical variable, the first electrical variable being an incident voltage at one of the input ports; and a second output signal from a detection unit proportional to a second electrical variable, the second electrical variable being a voltage reflected at said one of the input ports. Said incident voltage at one of the input ports can be a complex incident voltage and said voltage reflected in said one of the input ports can be a complex reflected voltage.

Each of the m input ports is indirectly coupled to an access from the radio unit (8), through one and only one of the detection units, said access from the radio unit delivering one and only one of the excitations. Each of the tuning unit setting instructions can be any type of digital message. Tuning unit setting instructions are issued during one or more setting sequences.

The multiple input and multiple output access tuning unit (4) is such that, at said given frequency, if the impedance matrix seen by the output ports is equal to a given non-diagonal impedance matrix, a application (in the mathematical sense) matching the impedance matrix presented by the input ports to the reactors is defined, the application having, at a given value of each of the reactors, a partial derivative with respect to each of the reactors, a vector subspace generated by the partial p derivatives being defined in the set of square complex matrices of order m considered as a real vector space, any diagonal complex matrix of order m having the same diagonal elements as at least one element of the vector subspace generated by the partial derivatives p. This should be interpreted as meaning: the tuning unit with multiple input access and multiple output access is such that, at said given frequency, there is a non-diagonal impedance matrix called the given non-diagonal impedance matrix, the matrix given non-diagonal impedance being such that, if an impedance matrix seen by the output ports is equal to the given non-diagonal impedance matrix, then an application matching an impedance matrix presented by the input ports to the p reactances is defined, l application having, at a given value of each of the p reactances, a partial derivative with respect to each of the p reactances, a vector subspace generated by the p partial derivatives being defined in the set of complex square matrices of order m considered as a real vector space, any complex diagonal matrix of order m having the same diagonal elements that at least one element of the vector subspace generated by the partial derivatives p.

The specialist knows that the dimension of the vector subspace generated by the partial derivatives considered as a real vector space has been used and explained: in international application No. PCI7IB2013 / 058423 (WO 2014/049475); and in sections I, III, VI, VII and VIII of the article by F. Broydé and E. Clavelier entitled “Some Properties of Multiple-AntennaPort and Multiple-User-Port Antenna Tuners”, published in IEEE Trans. on Circuits andSystems - I: Regular Papers, Vol. 62, No. 2, at pages 423-432, in February 2015. In the said article, the said dimension of the vector subspace generated by the partial derivatives is called “local dimension of the user port impedance range” and is denoted D _UR (Z _Sant ). A specialist understands that, in order to obtain that any diagonal complex matrix of order m has the same diagonal elements as at least one element of the vector subspace generated by the partial derivatives p, it is necessary that the dimension of the vector subspace generated by the partial derivatives p considered as a real vector space is greater than or equal to the dimension of the vector subspace of the diagonal complex matrices of order m considered as a real vector space. Since the dimension of the vector subspace generated by the partial derivatives p considered as a real vector space is less than or equal to p, and since the dimension of the vector subspace of the diagonal complex matrices of order m considered as a real vector space is equal to 2m, the necessary condition implies that p is an integer greater than or equal to 2m. This is why the requirement “p is an integer greater than or equal to 2m” is an essential characteristic of this embodiment.

The multiple input and multiple output access tuning unit (4) is such that it can provide, at said given frequency, for suitable values of the one or more tuning control signals, a transfer low-loss power transfer from the input ports to the output ports, and low-loss power transfer from the output ports to the input ports.

The specialist sees that the radio transceiver allows, at the given frequency, a transfer of power from the input m accesses to an electromagnetic field radiated by the antennas. In other words, the radio transceiver is such that, if power is received by the m input ports at the given frequency, part of said power received by the m input ports is transferred to a electromagnetic field radiated by the antennas at the given frequency, so that a power of the electromagnetic field radiated by the antennas at the given frequency is equal to said part of said power received by the m input ports. The radio transceiver also allows, at said given frequency, a transfer of power from an incident electromagnetic field on the antennas to the m access ports. In addition, the multiple input and multiple output access tuning unit (4) and the antennas (11) (12) (13) (14) are such that, at said given frequency, for values suitable for one or more tuning control signals, a low loss power transfer from the m input ports to an electromagnetic field radiated by the antennas can be obtained (for radio transmission), and a transfer low-loss power from an incident electromagnetic field on the antennas to the m input ports can be obtained (for radio reception). Thus, it is possible to say that the radio transceiver allows, at said given frequency, for suitable values of the one or more tuning control signals, a transfer of power with low losses from the m input ports up to an electromagnetic field radiated by the antennas, and a transfer of power with low losses from an electromagnetic field incident on the antennas to the m entry ports.

The appropriate values for the one or more chord control signals are provided automatically. Thus, the specialist understands that any small variation in the impedance matrix seen by the output ports can be at least partially compensated by a new automatic setting of the adjustable impedance devices of the tuning unit.

The radio transceiver is a portable radio transceiver, so the radio unit (8) also performs functions which have not been mentioned above, and which are well known to those skilled in the art. For example, the radio transceiver can be user equipment (in English: "user equipment" or "UE") of an LTE-advanced radio network.

The specialist understands that Z <,, „„ depends on the frequency and the electromagnetic characteristics of the volume surrounding the antennas. In particular, the user's body has an effect on Z <,, „„, and Z <,, „„ depends on the position of the user's body. This is called “user interaction”, or “main effect” (in English: “hand effect”) or “finger effect” (in English: “finger effect”). The specialist understands that the radio transceiver can automatically compensate for a variation in Z _{5on /} caused by a variation in an operating frequency, and / or automatically compensate for user interaction.

In order to respond to variations in the electromagnetic characteristics of the volume surrounding the antennas and / or of the operating frequency, a new adjustment sequence begins quickly after each change in the operating frequency, and no later than 10 milliseconds after the start of the previous setting sequence.

In this first embodiment, N = n = m = 4. Thus, it is possible that N is greater than or equal to 3, it is possible that N is greater than or equal to 4, it is possible that n is greater or equal at 3, it is possible that n is greater than or equal to 4, it is possible that m is greater than or equal to 3, and it is possible that m is greater than or equal to 4.

Second embodiment.

The second embodiment of a device according to the invention, given by way of nonlimiting example, also corresponds to the radio transceiver shown in FIG. 3, and all the explanations provided for the first embodiment are applicable to this second embodiment.

In this second embodiment, the radio transceiver uses the antennas simultaneously for radio communication ΜΙΜΟ.

In addition, in this second embodiment, the radio transceiver requests from the radio network the authorization to use, for excitations intended for internal adjustment of the radio transceiver, one or more data symbols, and the radio transceiver specifies the one or more data symbols it requests to use.

A full automatic setting of the multi-input and multiple-output access tuning unit requires several iterations, each iteration comprising the following steps: applying m excitations to the m input accesses; estimate q real quantities dependent on the impedance matrix presented by the input ports; issue a tuning unit setting instruction. Each iteration uses, for excitations, a single authorized data symbol, and only m elementary resources in this authorized data symbol, using the signal processing technique disclosed in the first embodiment of said international application number PCT / IB2015 / 057131.

Here, each iteration does not use, for the excitations, one or more data symbols comprising elementary resources allocated to reference signals for the estimation of the channel ΜΙΜΟ. Thus, an iteration does not result in an incorrect estimate of the channel ΜΙΜΟ. In addition, the authorized data symbols are grouped in a short time, so that a complete automatic setting of the tuning unit with multiple input access and multiple output access is fast enough. Therefore, we see that the invention overcomes the limitations of the state of the prior art.

Third embodiment.

The third embodiment of a device according to the invention, given by way of nonlimiting example, also corresponds to the radio transceiver shown in FIG. 3, and all the explanations provided for the first embodiment are applicable to this third embodiment. In addition, in this third embodiment, the radio network specifies the one or more authorized data symbols.

A full automatic setting of the multi-input and multiple-output access tuning unit requires several iterations, each iteration comprising the following steps: applying m excitations to the m input accesses; estimate q real quantities dependent on the impedance matrix presented by the input ports; issue a tuning unit setting instruction. Each iteration uses, for excitations, a single authorized data symbol, and only m elementary resources in this authorized data symbol, using the signal processing technique disclosed in the third embodiment of said international application number PCT / IB2015 / 057131.

Here, each iteration does not use, for the excitations, one or more data symbols comprising elementary resources allocated to reference signals for the estimation of the channel ΜΙΜΟ. Thus, an iteration does not result in an incorrect estimate of the channel ΜΙΜΟ. In addition, the authorized data symbols are grouped in a short time, so that a complete automatic setting of the tuning unit with multiple input access and multiple output access is fast enough. Therefore, we see that the invention overcomes the limitations of the state of the prior art.

INDICATIONS ON INDUSTRIAL APPLICATIONS

The method according to the invention is a precise and rapid method for automatically adjusting a tuning unit with multiple input access and multiple output access, and a precise and rapid method for automatically tuning an impedance matrix. The radio transceiver 5 according to the invention can precisely, quickly and automatically adjust its tuning unit with multiple input access and multiple output access, to precisely, quickly and automatically tune an impedance matrix.

The method and the radio transceiver according to the invention provide the best possible characteristics using very close antennas, therefore having a strong interaction between them. The invention is therefore particularly suitable for mobile radio transceivers, for example those used in portable radiotelephones or portable computers.

The method and the radio transceiver according to the invention provide the best possible characteristics by using a very large number of antennas in a given volume, thus exhibiting a strong interaction between them. The invention is therefore particularly suitable for high performance radio transceivers, for example those used in fixed stations of cellular radiotelephony networks.

Claims (10)

1. Method for automatically adjusting a multiple input access multiple output access tuning unit (4), the multiple input access multiple output access tuning unit having m input access and n output port, where m and n are each an integer greater than or equal to 2, the multiple input and multiple output access tuning unit comprising p devices with adjustable impedance, where p is an integer greater than or equal to m, the p devices with adjustable impedance being called “devices with impedance adjustable tuning unit ”and being such that, at a given frequency, each of the adjustable impedance devices of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the the tuning unit being electrically adjustable, the reactance of any of the adjustable impedance devices of the tuning unit being mainly determined by at least one tuning control signal, the tuning unit having multiple input access and multiple output access being part of a radio transceiver comprising TV antennas (11) (12) (13) (14) used to communicate in a radio network o, where TV is an integer greater than or equal to 2, the radio transceiver allowing, at the given frequency, a transfer of power from the m input accesses to an electromagnetic field radiated by the antennas, the method with the following steps: receive, from the radio network, a radio signal providing an authorization to use, for excitations intended for adjustment, one or more data symbols, each of said data symbols being called "authorized data symbol"; applying m excitations to the m entry ports, one and only one of the excitations being applied to each of the entry ports, the excitations existing inside one or more of the one or more authorized data symbols; pick up one or more electrical variables at each of the input ports, to obtain “detection unit output signals”, each of the detection unit output signals being mainly determined by at least one of the electrical variables picked up at one of the entrance entrances; estimate q real quantities dependent on the impedance matrix presented by the input ports, where q is an integer greater than or equal to m, using the output signals from the detection unit; use the said q real quantities dependent on the impedance matrix presented by the input ports, to obtain the one or more tuning control signals. 2. Method according to claim 1, in which 1 ’radio transceiver requests the radio network authorization to use, for excitations intended for adjustment, one or more data symbols. 3. The method of claim 2, wherein the radio transceiver specifies the one or more data symbols it requests to use. 4. The method of claim 1, wherein the radio network specifies the one or more authorized data symbols. 5. Radio transceiver for communicating in a radio network, comprising: N antennas (11) (12) (13) (14), where TV is an integer greater than or equal to 2; a multiple input and multiple output access tuning unit (4) having m input access and n output access, where m and n are each an integer greater than or equal to 2, the transceiver radio allowing, at a given frequency, a transfer of power from the m input ports to an electromagnetic field radiated by the antennas, the tuning unit with multiple input ports and multiple output ports comprising p devices with adjustable impedance, where p is an integer greater than or equal to m, the p devices with adjustable impedance being called the “devices with adjustable impedance of the tuning unit” and being such that, at the given frequency, each of the devices adjustable impedance of the tuning unit has a reactance, the reactance of any of the adjustable impedance devices of the tuning unit being electrically adjustable; m detection units (31) (32) (33) (34), each of the detection units delivering one or more “detection unit output signals”, each of the detection unit output signals being mainly determined by one or more electrical variables picked up at one of the input ports; a radio unit (8), the radio unit receiving, from the radio network, a radio signal providing an authorization to use, for excitations intended for adjustment, one or more data symbols, each of said data symbols being called “Authorized data symbol”, the radio unit applying m excitations to the m input ports, one and only one of the excitations being applied to each of the input ports, the excitations existing inside one or more of the one or more authorized data symbols, the radio unit estimating q real quantities dependent on the impedance matrix presented by the input ports, where q is an integer greater than or equal to m, using the unit output signals of detection, the radio unit delivering one or more “tuning unit setting instructions”, at least one of the one or more tuning unit setting instructions being determined by function of q real quantities dependent on the impedance matrix presented by the input ports; and a control unit (6), the control unit receiving the tuning unit setting instructions, the control unit supplying one or more “tuning control signals” to the tuning unit with multiple input access and multiple output access, each of the tuning control signals being determined as a function of at least one of the tuning unit setting instructions, the reactance of each of the impedance adjustable devices of the tuning unit being mainly determined by at least one of the one or more tuning control signals. 6. A radio transceiver according to claim 5, in which the detection unit output signals delivered by each of the detection units comprise: a first detection unit output signal proportional to a first electrical variable, the first electric variable being a voltage across one of the input ports; and a second detection unit output signal proportional to a second electrical variable, the second electrical variable being a current entering said one of the input ports. 7. A radio transceiver according to claim 5, in which the detection unit output signals delivered by each of the detection units comprise: a first detection unit output signal proportional to a first electrical variable, the first electric variable being an incident voltage at one of the input ports; and a second output signal from a detection unit proportional to a second electrical variable, the second electrical variable being a voltage reflected at said one of the input ports. 8. A radio transceiver according to any one of claims 5 to 7, in which the radio transceiver requests from the radio network the authorization to use, for excitations intended for adjustment, one or more data symbols. . 9. The radio transceiver according to claim 8, wherein the radio transceiver specifies the one or more data symbols it requests to use. 10. The radio transceiver according to any of claims 5 to 7, wherein the radio network specifies the one or more authorized data symbols.