DEVICE FOR CONTROLLING A SCANNING ACTIVE ANTENNA

Abstract

A device for controlling the efficiency of a scanning active antenna includes at least two transmission paths Tx.sub.i, a transmission path comprising a phase control module, and a power stage at the output of which a radiating element is arranged, comprising at least: a voltage modulator located upstream of the power stage of each of the radiating elements, a control device transmitting a PWM drain voltage control signal configured so as to manage the gain of a power stage in accordance with a predefined first bias law and to control the phase applied to the drain of the power stage in accordance with a second bias law.

Claims

1. A device for controlling a scanning active antenna comprising at least two transmission paths Tx.sub.i, a transmission path comprising a phase control module (2.sub.i), and a power stage (3.sub.i) at the output of which a radiating element E.sub.i is arranged, comprising at least: a voltage modulator (5.sub.i) located upstream of the power stage (3.sub.i) of each of the radiating elements E.sub.i, a control device transmitting a PWM drain voltage control signal configured so as to manage the gain of a power stage in accordance with a predefined first bias law and to control the phase applied to the drain of the power stage in accordance with a second bias law.

2. The device according to claim 1, wherein the power stage is a power transistor, said modulator being designed to manage the drain voltage of the power transistor.

3. The device according to claim 1, wherein the first bias law for managing the gain and the second bias law for phase control are defined when the system is calibrated.

4. The device according to claim 1, wherein the control signal is determined taking into account the computation of the altitude and azimuth of the radiation desired at the antenna.

5. The device according to claim 1, wherein the antenna elements are configured so as to operate in frequency bands above 800 MHz.

6. The device according to claim 1, wherein the antenna elements are configured so as to operate in the field of 4G/5G communications.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] Other features, details and advantages of the invention will become apparent from reading the description, given with reference to the appended drawings, which are given by way of non-limiting example and in which, respectively:

[0019] FIG. 1 shows an example of an architecture according to the prior art,

[0020] FIG. 2 shows an example of a system according to the invention,

[0021] FIG. 3 shows an example of a bias law for the amplifier, which makes it possible to manage the gain thereof on the basis of the drain voltage, and of a bias law for controlling the phase on the basis of the drain voltage.

DETAILED DESCRIPTION

[0022] Active antenna systems use uniformly distributed active modules, each of these modules notably comprising a high-frequency power amplifier (HPA) used for transmission. Each active module transmits a portion of the power needed by the antenna system to provide a given range status. The various transmission sources are summed coherently in an antenna array comprising a large number of sources. With all of the active modules being identical, it is generally sought to optimize efficiency and range status by making the power amplifiers operate in saturated mode, that is to say at maximum power.

[0023] The idea of the present invention is to integrate, directly into the power stage, a voltage modulator in each active cell of the antenna array. The voltage modulator notably has the role of managing the transmission power of each of the active elements in terms of the drain voltage of the power transistor, thus making it possible to reach a unitary optimum efficiency and therefore a global optimum efficiency for the antenna array. The corollary effect is that of increasing the efficiency of each amplifier when these are used below their saturated power, and therefore of reducing the overall consumption of the active antenna in comparison with the current prior art. In addition, using the very fast voltage modulator, such as the one disclosed in patent application WO2020016305, makes it possible to control the gain of the power amplifiers more quickly, by a factor of at least 100 in comparison with the current prior art. This enables additional functionalities for the active antenna, such as dynamic target tracking, or instantaneous communication with two different targets.

[0024] FIG. 2 illustrates an example of an architecture according to the invention, in which the elements of FIG. 2 in common with those of the system described in FIG. 1 bear the same references.

[0025] The system comprises a set of n active antenna elements: E.sub.i=E.sub.1, . . . E.sub.n.

[0026] A transmission chain Txi comprises a phase adjustment device 2.sub.i positioned upstream of an amplifier 3.sub.i, which is itself located upstream of an active antenna element.

[0027] An ultra-fast device 5.sub.i for modulating the drain voltage is connected to the output amplifier 3.sub.i. A PWM control signal generated by a control device 10 is sent to this drain voltage modulation device in order to manage the gain of the output amplifier and thus improve the pointing of the active antenna. The control device is also configured so as to control the phase applied to the drain of the amplifier. The speed of the drain voltage control system makes it possible to reconfigure the antenna with a far greater speed (at least 10 times faster) than systems known from the prior art.

[0028] FIG. 3 gives an example of bias laws implemented by the control device 10. A bias law for the amplifier (FIG. 3) is implemented in an FPGA (field-programmable gate array) programmable logic circuit or ASIC (application-specific integrated circuit) integrated circuit. The bias law is extracted when the antenna system is calibrated and makes it possible to accurately ascertain the gain G of the amplifier on the basis of the drain voltage Vds applied thereto (FIG. 3). The curve 31 corresponds to the bias law that makes it possible to manage the gain G of the amplifier on the basis of the drain voltage, and the curve 32 corresponds to the control of the phase ϕ on the basis of the drain voltage Vds of the power amplifier. The aim is to remain within a phase variation less than 5° in order to control the antenna correctly.

[0029] This novel way of controlling the output power of a power amplifier by varying its gain through the applied drain voltage is not used in the prior art. The output power of each amplifier is usually adjusted on the basis of its input power applied thereto.

[0030] The extracted bias law is used to compute the drain voltage to be applied to each power amplifier forming the active antenna for an azimuth and altitude configuration of the antenna.

[0031] An analogue PWM signal carrying the information about the voltage to be applied to each amplifier is sent to the drain voltage modulation circuit. This signal is computed in relation to the altitude and azimuth computation for the desired radiation of the antenna.

[0032] The self-protection circuit described in patent FR3134972 may be positioned at the output of each power amplifier so as to make it possible to protect each element from excessive mismatching. This circuit may be coupled to the novel very fast active antenna architecture.

[0033] The invention applies in the field of active antennas operating in frequency bands above 800 MHz, Satcom, 4G/5G networks, etc.

[0034] The prior art uses a fixed bias on each amplifier, thereby causing consumption losses when these are not used at full power. By proceeding with the method according to the invention, there is a dual gain on the system: a gain in terms of consumption when the amplifiers are used below their maximum power and a gain in terms of the radiation pattern, which becomes more directional by virtue of optimizing the amplitude on each amplifier.

[0035] The use of this novel architecture also allows much faster control of the pointing/depointing of the antenna (at least ten 10 times faster). This allows much more effective target tracking, and also opens up the possibility of tracking and interacting with multiple targets almost instantaneously.