SYSTEM AND METHOD FOR DYNAMICALLY CALIBRATING ONE OR MORE RADIOFREQUENCY CHANNELS FOR TRANSMITTING A

专利摘要:
A dynamic calibration system of a first radio frequency channel (6) to be calibrated comprises: an injection device (32) for a calibration signal whose waveform is predetermined, connected upstream of the radio frequency chain calibrating, and .- a compensating device (34) amplitude and phase disparities caused by the first chain (6) to calibrate including a controlled compensation filter. The automatic calibration system is characterized in that it comprises a device for temporally erasing (36) the calibration signal injected with the aid of an analog or digital subtracter (38), said subtractor (38) being connected by downstream of the first radio frequency chain (6) to be calibrated.
公开号:FR3049794A1
申请号:FR1600565
申请日:2016-04-04
公开日:2017-10-06
发明作者:Yann Nicolas Pierre Oster；Aubin Michel Lecointre
申请人:Thales SA；
IPC主号:

专利说明:

System and method for dynamic calibration of one or more radio frequency transmission channels of a satellite payload
The present invention relates to a system and a method for dynamically calibrating one or more radio frequency RF transmission channels of a satellite payload for which said dynamic calibration of the radio frequency chain is implemented without interrupting the transmission of the useful signal through the RF chain, and for which the waveform of the compensated useful signal, obtained at the output of the RF chain during and after calibration, is slightly degraded.
In general, the performance of a radio circuit forming at least one RF radio frequency chain of analog functions placed in series in different combinations, such as for example an RF amplification, a frequency transposition, a filtering, are affected by unpredictable deviations and variables resulting for example from the manufacture, the sensitivity to the temperature of the environment, the aging of the components and their exposure to ionizing radiations.
In particular, the performance of the circuits of the telecommunications payloads aboard the satellites undergo such unpredictable effects.
Thus, for a conventional telecommunications payload comprising a small number of RF radio frequency chains and SFPB (Single Feed Per Beam) single source antennas, a requirement is typically asked to estimate and compensate for the response. spectral strings, in order to equalize the gain and the group delay on the useful band. In the case of a telecommunications payload employing an active antenna and a large number of radio frequency channels or associated RF channels, the requirement is not only for an equalization for each channel of the spectral response on the wanted band , but also an equalization of the dispersions in phase and amplitude between the channels on the useful band. Indeed, the radio performance of the active antennas are particularly sensitive to phase differences between channels, and the requirement of the tolerance of such phase shifts is particularly severe, especially for implementing an anti-jamming function.
In order to control amplitude and phase dispersions by channel or between channels, a first family of so-called static conventional solutions has been implemented and is still used today, particularly in the space domain.
A first static solution of said first family consists in over-constraining the specification requirements of the technical performance of each component or equipment of the radio frequency chain, so that the sum of the gain and phase dispersions over the useful band, caused by the all components of the radio frequency chain, remains compatible with the desired level of performance for the expected service life.
This first conventional technique which over-constrains the design, manufacture, supply, and adjustment in phase of integration of the components of the chain or chains, corresponds to a conservative approach. This approach has the effect of significantly increasing manufacturing costs. Moreover, since the residual dispersions are not dynamically compensated, the dispersions remain significant and certain functions such as anti-jamming can not always be performed.
A second static solution of said first family is to characterize the behavior of the elements or equipment, in terms of sensitivity to temperature and / or supply voltage, then to implement a static compensation function, using temperature measurement and / or supply voltage, and set in phase AIT (English Assembly, Integration and Test), specifically for each instance. This type of solution allows a static correction but does not allow a capacity of adaptation to the real gaps which can widen, in particular because of the aging and the effect of the radiations undergone by the components of the radiofrequency chain in orbit.
In order to remedy the disadvantages presented by the first and second static solutions of the first family of solutions, a second family of so-called dynamic solutions is described in the article by A. Lecointre et al., Entitled "On-Board Self Calibration Techniques". and published at the ESA Workshop from 17-19 April 2012: "ESA workshop on advanced flexible telecom payloads". This document reviews the dynamic calibration techniques used to date or under development, and evaluates the effect of the calibration signal on the nominal service or communication signal depending on the calibration technique used.
Each dynamic solution, described in the article by A. Lecointre et al., Consists in estimating the amplitude and / or phase deviations on the radio frequency channel (s), using a known calibration signal, injected at the input and extracted in output of the radio frequency chain. The deformation of the calibration signal at the output of the radiofrequency channel makes it possible to estimate the spectral response in real time, and to compensate for the defects of the response by means of a feedback loop. This type of looped, dynamic solution makes it possible to advantageously adapt to defects, regardless of their origin and unpredictable variability in their occurrence, such as a defect caused by aging and / or radiation.
In order to be able to inject and extract the measurement signal used for calibration, a first dynamic solution of said second family is to suspend the useful telecommunication service for a period of time with the disadvantage of degrading the quality of the service.
A second dynamic solution of said second family consists in spreading the spectrum of the calibration signal in order to be able to superpose it on the useful traffic signal without unduly disturbing said useful signal, and thus to avoid the interruption of the telecommunication service. However, in this case the calibration measurement is affected by a low ratio of the level of the calibration signal measured on the noise level and interference SNIRcai (in English "calibration Signal to Noise and Interference Ratio") and the spreading of the measured point in frequency, the estimate of defects corresponding to an average of the defects on the spread band.
A third dynamic solution of said second family consists in injecting the calibration signal on frequencies not used by the communication services on guardbars with the disadvantage of a poor granularity of the frequencies used for the estimation of the dispersion. amplitudes and / or in phases on the band of the chain to be calibrated.
A first technical problem is to improve the quality of correction or compensation of the response of a radio frequency band to the useful band of the radiofrequency chain, which is obtained by a correction or compensation performed by a method and a calibration system. dynamic using the techniques described above.
A second technical problem is to limit the level of interference experienced by the calibration signal and having as source the useful communication signal when the compensation method is implemented without interruption of the useful communication service.
A third technical problem is to minimize the distortion caused by the calibration signal on the useful communication signal at the output of the string under calibration when the calibration is active. For this purpose, the subject of the invention is a system for dynamically calibrating a radio frequency circuit of a satellite payload, the RF radio frequency circuit comprising a first radio frequency channel to be calibrated for amplification and filtering with or without transposition to a predetermined transposition frequency of a first input signal formed by the time sum of a second calibration signal and a third input useful signal, the first radio frequency channel to be calibrated on a useful channel of a string being comprised between upstream a first upstream port receiving the first input signal and downstream a first downstream port providing a first output signal, the first output signal being the frequency and time response of the radio frequency chain to be calibrated at first input signal; and the automatic calibration system comprising: a device for injecting the second calibration signal whose waveform is predetermined upstream of the first radio frequency channel to be calibrated, the second calibration signal being injected directly in digital form or indirectly in analog form through a second analog injection chain from a reference calibration signal, and the band of the second calibration signal being included in the useful band of the first channel to be calibrated; and a device for compensating for the frequency and frequency response of the first radio frequency channel to be calibrated, comprising a compensation filter on the useful frequency band of the first channel to be calibrated, the compensation filter being arranged upstream or downstream. the first radio frequency channel to be calibrated and the compensation being made from measurements of a fourth signal, observed downstream of the first radio frequency channel to be calibrated and the compensation filter, or directly ahead of the first channel to be calibrated; the automatic calibration system being characterized in that it comprises: a device for temporally erasing the second injected calibration signal having an analog or digital subtractor connected downstream of the first radio frequency channel to be calibrated.
According to particular embodiments, the dynamic calibration system comprises one or more of the following characteristics: the analog or digital subtractor is connected downstream of the first radio frequency channel to be calibrated and downstream of the compensation filter, or the digital subtracter is connected upstream the first radio frequency channel to be calibrated and downstream the compensation filter; the temporal erasure device also comprises a third digital or analog supply chain of a replica of the reference calibration signal to be subtracted, adapted in terms of the frequency of compatible transposition of the output frequency of the radio frequency channel to be calibrated, of compatible delay of the propagation times of the signal through the injection device and the first radio frequency channel to be calibrated, or through the injection device, of the first radio frequency channel to be calibrated and of the compensation filter; and the time erasure device is configured to coherently subtract the adapted replica of the reference calibration signal from the output signal of the first radio frequency channel to be calibrated; the dynamic calibration system further comprises a first generator of one or more local oscillator signals OL identical to a phase shift and synchronized to a first reference clock; and when the first radio frequency channel to be calibrated comprises one or more frequency transposition circuits; and / or when the second injection channel is analogue and comprises one or more frequency transposition circuits; and / or when the third supply chain of the adapted replica is analogue and comprises one or more frequency transposition circuits, the first transposition circuit or circuits, and / or the second or the second transposition circuit, and / or the the third transposition circuits are configured so as to use the same signal of the oscillator iocai to a phase shift close and réaiiser the up or down frequencies transpositions: when the injection of the calibration signal is digital, the injection device of the signal of calibration comprises a digital generator of a digital reference calibration signal and a digital summator of the reference calibration signal to a digital traffic signal; and when the injection of the calibration signal is analog, the calibration signal injection device comprises a digital generator of a digital reference calibration signal, a digital-to-analog converter, and a second analog injection chain including an analog coupler operating as a summator of two analog signals; and the calibration signal injection device is configured to adjust the power of the second calibration signal dynamically relative to that of the third useful signal to the highest possible compatible level of no saturation of an analog-to-digital converter or digital-analog of the first radio frequency channel to be calibrated, disposed respectively at the output or at the input of said first channel; the first radio frequency channel to be calibrated is an analog chain of a communication receiver comprising a first frequency down-converting circuit, a first upstream amplification stage disposed upstream of the first transposition circuit, a first amplification downstream stage disposed downstream of the first transposition circuit, and a first output analog-to-digital converter connected to the output of the first channel to be calibrated; and the calibration signal injection device comprises, put in series, a digital generator of a digital reference calibration signal, a digital-analog converter, and a second analog injection chain including an analog coupler operating as a summator two analog signals; and the injection device is configured to inject one or more calibration signals of a time sequence covering the useful frequency band over which the first string is to be calibrated, and to add the one or more calibration signals to the third useful traffic signal ; and the temporal erasure device comprises the digital generator of the digital reference calibration signal shared with the injection device, a digital subtracter, and a third digital supply chain of a replica of the reference calibration signal to be subtracted. , adapted in terms of a compatible transposition frequency of the output frequency of the radio frequency channel to be calibrated and a compatible delay of the propagation time of the signal along the propagation path traversing successively the injection device, the first radio frequency channel to be calibrated and the compensation filter; the device for compensating the frequency and frequency response of the first radio frequency channel to be calibrated comprises a compensation filter and an adaptive or bulk optimizer of the coefficients of the compensation filter, the compensation filter being arranged directly downstream of the first channel radio frequency to be calibrated and directly upstream of the digital subtracter of the temporal erasure device, and the adaptive optimizer is configured to determine commands of the compensation filter coefficients from measurements of a fourth observed signal taken directly downstream of the digital subtracter, and from the reference calibration signal from the reference generator; the first radio frequency channel to be calibrated is an analog channel of a communication receiver comprising a first frequency down-converting circuit, a first upstream amplification stage arranged upstream of the first transposition circuit, a first amplification downstream stage arranged downstream of the first transposition circuit, and a first output analog-to-digital converter, connected at the output of the first channel to be calibrated; and the calibration signal injection device comprises, put in series, the digital generator of a digital reference calibration signal, the digital-analog converter, and a second analog injection channel including an analogue coupler operating as a summator two analog signals; and the injection device is configured to inject one or more calibration signals of a time sequence covering the useful frequency band on which the first channel is calibrated, and to add the one or more calibration signals to the third useful traffic signal; and the temporal erasure device comprises the digital generator of the digital reference calibration signals of the time sequence shared with the injection device, the digital subtracter, and a third digital supply chain of the replicas of the reference calibration signals. of the sequence to be subtracted, adapted in terms of a compatible transposition frequency from the output frequency of the radio frequency channel to be calibrated, of gains and delays compatible respectively with the gains and the propagation times of the calibration signals along the path propagation device successively passing through the injection device and the first radiofrequency channel to be calibrated; the third digital channel comprises the calibration controller, configured to estimate characteristic parameters of the timing sequence calibration signals from the fourth observed current signal, and configured to determine characteristic parameters of replicas adapted to the calibration signals of the sequence from sequence calibration signals generated by the reference calibration signal generator and estimated characteristic parameters; and a digital replica generator adapted to the observed calibration signals and to be subtracted; the device for compensating the frequency and frequency response of the first radio frequency channel to be calibrated, comprises a compensation filter and a control circuit of the coefficients of the compensation filter, the compensation filter being connected directly downstream of the digital subtracter, said subtractor being disposed directly downstream of the first radio frequency channel to be calibrated; and the control circuit being configured to determine commands of the coefficients of the compensation filter from several measurements of a fourth observed signal taken directly downstream of the first channel to be calibrated and from the reference calibration signal from the generator reference ; the first radio frequency channel to be calibrated is an analog chain of a communication transmitter comprising a first frequency up-converting circuit, a first amplification upstream stage disposed upstream of the first transposition circuit, a first amplification downstream stage disposed downstream of the first transposition circuit, and a first digital-to-analog input converter, connected at the output of the compensation filter; the calibration signal injection device comprises, put in series, a digital generator of a digital reference calibration signal, and a second digital injection chain comprising a numerical summator of two digital signals; and the time erasing device comprises the digital generator of the digital reference calibration signal shared with the injection device, the analog subtractor, and a third digital-analog hybrid chain for providing a replica of the calibration signal of reference to subtract, adapted in terms of a compatible transposition frequency of the output frequency of the first radio frequency channel to be calibrated and a compatible delay of the signal propagation delays along the propagation path traversing successively the device of injection, the compensation filter and the first radio frequency channel to be calibrated; the third hybrid chain comprises putting in series a third digital sub-string and a third analog sub-string, the third digital sub-string including in series; a digital reproduction circuit of a reference numerical model of a temporal and frequency response of the first radio frequency band and the compensation filter of the first string when the compensation performed by the compensation filter is optimal, and of the dispersion correction in amplitude and in phase caused by the third analog sub-chain, and a third digital-to-analog converter; and the third analog sub-channel including a third frequency up-converting circuit, a third upstream amplifier stage disposed upstream of the third transposition circuit, a third power amplifier downstream stage disposed downstream of the third transposition circuit. ; the device for compensating the frequency and frequency response of the first radio frequency channel to be calibrated comprises a digital compensation filter and an adaptive or bulk optimizer of the coefficients of the digital compensation filter, the compensation filter being arranged directly upstream. of the first radio frequency channel to be calibrated, and directly downstream of the digital summator, and the adaptive optimizer is configured to determine commands of the compensation filter coefficients from measurements of a fourth observed signal, taken directly downstream of the subtractor analog and from the reference calibration signal from the reference generator; the compensating device further comprises a fourth measurement channel for measuring measurements of the fourth observed signal taken directly downstream of the analog subtractor to the adaptive optimizer, the fourth measurement channel including a fourth frequency down-converting circuit. a fourth amplification upstream stage disposed upstream of the fourth downconverter circuit, a fourth downstream amplification stage disposed downstream of the fourth transposition circuit; the dynamic calibration system further comprises a second generator of one or more sampling clock signals derived from a common reference clock signal provided by a second reference clock; and when the first radio frequency channel to be calibrated comprises an ADC analog-digital converter and / or a DAC digital-to-analog converter, and / or when the second injection channel is analogue and comprises a digital-analog DAC converter; and / or when the third supply chain of the adapted replica is analogue and comprises a DAC digital-to-analog converter; and / or when the fourth measurement chain is analog and includes an ADC analog-to-digital converter; and / or the digital-to-analog converter (s), and / or the digital-to-analog converter (s) are synchronized with one another through the local clock or local oscillator, shared and considered As the master, all analog-to-digital ADC and digital-to-analog converters DAC are configured to use the one or more sampling clock signals derived from the common reference clock signal provided by the second reference clock. The subject of the invention is also a method of dynamically calibrating a radio frequency circuit of a satellite payload, the radio frequency circuit comprising a first radio frequency channel to be calibrated for amplification and filtering with or without transposition at a transposition frequency. predetermined value of a first input signal formed by the time sum of a second calibration signal and a third input useful signal, the first radio frequency channel to be calibrated on a useful channel of the string being between an upstream one first upstream port receiving the first input signal and downstream a first downstream supplying port of a first output signal, the first output signal being the frequency and time response of the first radio frequency channel to be calibrated at the first signal d 'Entrance; the dynamic calibration method comprising the steps of: in a first step, an injection device injects a second calibration signal whose waveform is predetermined upstream of the first radiofrequency channel to be calibrated, the second signal calibration being directly injected in digital form or indirectly in analog form through a second analog injection chain from a reference calibration signal; then in a second step, a compensation device compensates, on the useful band of frequencies of the first string to be calibrated, amplitude and phase disparities caused by the first string to be calibrated, using a compensation filter , disposed upstream or downstream of the first radio frequency channel to be calibrated, the compensation being made from measurements of a fourth signal, observed downstream of the first radiofrequency channel to be calibrated and the compensation filter, or directly downstream of the first string to calibrate; and the dynamic calibration method being characterized in that it comprises a third step, performed after the first step, during which a temporal erasing device temporally erases the calibration signal injected with the aid of an analog subtractor. or digital, connected downstream of the first channel to be calibrated.
According to particular embodiments, the calibration method comprises one or more of the following characteristics: the third step is executed after the second step, the subtractor is an analog subtractor connected directly downstream of the first channel to be calibrated, and the compensation filter is a digital compensation filter arranged upstream of the radio frequency chain to be calibrated, when the first channel is the chain of an emitter; or the third step is executed after the second step, the subtractor is a digital subtractor, connected directly downstream of the compensation filter, and the compensation filter is a digital compensation filter, arranged directly downstream of the first channel to be calibrated, when the first channel to be calibrated is the chain of a receiver; or the third step is executed before the second step, the subtractor is a digital subtractor connected directly upstream of the first channel to be calibrated and downstream the compensation filter, and the compensation filter is a digital compensation filter, arranged directly in downstream of the digital subtracter, when the first channel to be calibrated is the chain of a receiver. The invention proposes a solution to the problem of the dynamic calibration of reception and transmission processing chains including analog functions, sources of dispersion of the frequency response.
Contrary to known methods, this solution makes it possible to apply a high-amplitude measurement signal in narrow band or in broadband, without additional spectrum spread, and without significant impact on the quality of the useful signal (the traffic signal in the case a telecommunications payload) transmitted at the output of the chain in terms of no interruption of service and no interference.
This solution reconciles calibration performance thanks to a measurement of the high SNR calibration signal (in English "Signal to Noise Ratio") and transparency for the useful telecommunications service in terms of no interruption of service and absence of interference with the useful signal.
The need for calibration is particularly relevant to the payloads of onboard telecommunications satellites, which are confronted with cyclical variations in temperature, power, and the effect of radiation and aging on lifetimes that may exceed fifteen. The invention will be better understood on reading the description of several embodiments which follows, given solely by way of example and with reference to the drawings in which: FIG. 1 is a view of a first embodiment of embodiment according to the invention of a dynamic calibration system of a radio frequency transmission chain of a satellite payload in the case where the chain is that of a receiver circuit; Figure 2 is a flow chart of a first embodiment according to the invention of a dynamic calibration method of a radio frequency transmission chain of a satellite payload. corresponding to the implementation of the dynamic calibration system of Figure 1; FIG. 3 is a view of a second embodiment according to the invention of a dynamic calibration system of a radio frequency transmission chain of a satellite payload in the case where the channel is that of a circuit receiver; FIG. 4 is a flowchart of a second embodiment according to the invention of a method for dynamically calibrating a radiofrequency channel for transmitting a satellite payload, corresponding to the implementation of the dynamic calibration system. of Figure 3; FIG. 5 is a view of a third embodiment according to the invention of a dynamic calibration system of a radio frequency transmission chain of a satellite payload in the case where the channel is that of a circuit issuer; FIG. 6 is a flowchart of a third embodiment according to the invention of a method for dynamically calibrating a radio frequency transmission chain of a satellite payload, corresponding to the implementation of the dynamic calibration system. of Figure 5; Figure 7 is a view of a fourth embodiment according to the invention of a dynamic calibration system of a set of N radiofrequency transmission channels of a satellite payload; Figures 8A and 8B are flowcharts of a general method of dynamically calibrating a radio frequency chain of a satellite payload encompassing the dynamic calibration methods of Figures 2, 4 and 6.
According to Figure 1 and a first embodiment, a dynamic calibration system 2 of an RF radio frequency circuit 4 of a satellite payload is shown.
The RF radio frequency circuit 4 to be calibrated comprises a first transmission RF analog radio frequency channel 6 to be calibrated on a useful channel of the channel, the first analog radio frequency channel 6 being between, upstream, a first upstream port 8 for receiving a first input radio frequency signal and, downstream, a first downstream port 10 for providing a first output signal.
The first digital output signal is the frequency and time response of the first analog channel 6 to be calibrated at the first input radio frequency signal.
The first analog radio frequency channel 6 to be calibrated is here an analog chain of a communication receiver which comprises a first frequency down-converter transposition circuit 12, a first upstream amplification stage 14, arranged upstream of the first transposition circuit 12, a first amplification downstream stage 16, arranged downstream of the first transposition circuit 12, and a first analog-to-digital converter ADC (analog to digital converter) whose digital output is connected to the first downstream port 10 of the first analog radio frequency channel 6 to be calibrated. The upstream to downstream direction of the first channel 6 is represented by an arrow 20, oriented from the RF input port 22 to the RF output port 24 of the down-converter transposition circuit 12.
In general, the first radio frequency channel to be calibrated may contain any number of amplifiers, greater than or equal to one, and not necessarily limited to two amplifiers.
In a variant, the first radio frequency channel to be calibrated may be devoid of frequency transposition by mixer and local oscillator.
The automatic calibration system 2 comprises: an injection device 32 of a second caiibration signal whose waveform is predetermined, arranged at the input and upstream of the first analog radio frequency channel 6 to be calibrated, and a device for compensation 34 of the frequency and time response of the first radio frequency chain 6 to be calibrated on the useful band of the first channel 6, and a temporal erasure device 36 of the second injected calibration signal having a digital subtracter 38.
The injection device 32 of the second calibration signal comprises, put in series and successively, a digital generator 39 of a second digital reference calibration signal, a second digital-analog converter 40 DAC (in English Digital to Analog Converter) , and a second chain 42, here of analog injection.
The second analog injection chain 42 includes at the output end an analog coupler 44, configured to function as an adder or analogue adder of two analog signals, the two analog signals being formed by a third input useful signal and the second signal injected calibration.
The second calibration signal has a useful bandwidth less than or equal to the useful bandwidth of the first string to be calibrated.
The second channel 42, here analog injection, has an input port 46, connected to the analog output of the second digital-to-analog converter DAC 40.
The second analog injection chain 42 here comprises a second frequency-up transposition circuit 48, a second upstream amplification stage 50, arranged upstream of the second transposition circuit 48, a second amplification second stage 52, arranged in downstream of the second transposition circuit 48.
The injection device 32 is here configured to inject, at the upstream input port 8 of the first analog channel 6 to be calibrated, the second calibration signal which has the same waveform, at a frequency transposition, the reference digital calibration signal, generated by the reference generator 39. The injection of the second calibration signal takes place through the analog coupler 44 which comprises a first injection input port 56 connected to the output of the an antenna source, a second injection input port 58, connected downstream of and to the analog radio frequency output of the second analog channel 42, and a third injection output port 60, connected to the port of Upstream input 8 of the first analog channel 6 to be calibrated.
The first injection input port 56 is configured to receive the third input useful signal, for example a communication traffic signal, designated Su (t), while the second injection input port 58 is configured to receive the second calibration signal. designated by Scai (t) and supplied at the output of the second analog injection line 42.
The third injection output port 60 is configured to supply at input 8 of the first channel 6 to calibrate the first input signal Sy (t) + K.Scai (t), equal to the time sum of the traffic signal Su (t) and the coupled calibration signal K.Scai (t), K designating a coupling factor of the summing coupler 44.
The injection device 32 is configured to inject the second calibration signal at a high level, to make it possible to optimize the accuracy of the estimation of the spectral and temporal response of the first channel to be calibrated, and to make it possible to optimize the compensation of the chain to be calibrated.
In practice, the power of the second calibration signal is adjusted dynamically relative to that of the useful signal so as not to saturate the first ADC output analog converter 18. The adjustment is for example made at the digital generation 39 of the signal the second analog channel 42 having a constant gain.
Here, the frequency of the transposition signal of the first step-down circuit and the frequency of the second step-up circuit are identical and the transposition signal is provided by the same local oscillator 64, slaved to a master reference clock, not shown in FIG. Similarly, the sampling clocks of the analog-digital output converter 18 of the first channel 6, the digital input converter 40 of the second analog channel 42, and the digital generator 39 of the reference calibration signal are synchronized here. preferably on the reference master clock.
In general, all the mixers of the different channels use the same local oscillator OL signal, with a phase shift, to carry out the transpositions of rising or falling frequencies.
In general, all analog-digital ADC and digital-to-analog converters DAC use one or more sampling clock signals derived from a common reference signal.
In a variant, the local oscillator signal OL used for the transpositions is neither identical nor derived from the same clock reference as the clock signal common to ADC and DAC analog-to-digital converters.
The compensation device 34 of the frequency and time response of the first radio frequency channel 6 to be calibrated here comprises a compensation filter 66 on the frequency band of the first analog channel 6 to calibrate amplitude and phase disparities caused by the first analog channel 6 to be calibrated, and an optimizer 68 of the coefficients of the compensation filter.
The compensation filter 66 is disposed here directly downstream of the first radio frequency chain 6 to be calibrated and directly upstream of the digital subtracter 38 of the temporal erasure device 36. The compensation filter 66 comprises an input port 70, connected to the first downstream port 10 of the first channel 6, and an output port 72, connected to a first port 74 of the input of the digital subtracter 38.
The compensation filter 66 is configured to implement the compensation from filter coefficient commands of said compensation filter 66, the commands being determined from measurements of a fourth observed signal, taken here directly downstream of the subtractor. a port 76 for taking measurement (s). The optimizer 68 is here an optimizer using an adaptive processing, that is to say an iterative or recursive processing within a servocontrol, or using a block processing of a set of samples measured in block, connected here between the measurement port 76 and a control port 78 of the compensation filter 66. The optimizer 68 is configured to determine the commands of the coefficients of the compensation filter 66 from measurements of the fourth observed signal, taken directly downstream of the digital subtracter 38 at the measurement port 76 and from the second reference calibration signal from the digital generator 39.
In general and according to various variants, the adaptive optimizer or block 68 can operate indifferently on the measurement points 70, 72 or 74, and 76, sequentially or jointly, according to the optimization algorithm used. Indeed, depending on the progress of the calibration process, or depending on the type of optimization algorithm used, the measurement can be done at different points (ie the points 70, 72, or 76) for improve the performance and facilitate the convergence of the algorithm. The objective of the optimizer is to configure, via the control port 78, a compensation actuator (a compensation filter 66 for Figure 1 or another device) from measurements of one of the points 70, 72 or 76, chosen as the measuring point and the reference calibration signal from the generator 39 of the reference calibration signal. Thus the optimizer comprises a second input terminal for receiving the reference calibration signal from the generator 39 of the calibration signal. The algorithm used in the optimizer can operate in the time or frequency domain, iteratively / recursively or by block of samples. The algorithms used in the optimizer can be indifferently: Fourier Transform algorithms, least squares type algorithms, for example Least Square (LS) algorithms, Least Mean Square (LMS) algorithms, RLS (in English "Recursive Least Squares"), algorithms using covariances or correlations, algorithms type CMA (Covariance Matrix Adaptation ").
The temporal erasure device 36 comprises the digital generator 39 of the second digital reference calibration signal shared with the injection device 32, the digital subtracter 38, and a third digital string 80 for supplying a replica of the digital signal. reference calibration to subtract, adapted in terms of a compatible transposition frequency of the output frequency of the first radio frequency channel 6 to be calibrated, and a gain and delay compatible gains and delays of the signal along the propagation path successively traversing the injection device 32, the first radiofrequency channel 6 to be calibrated and the compensation filter 66.
Here, the third digital channel 80 comprises a modeling circuit 82 or a "model" of numerical reference of the temporal and frequency response of the first channel 6 to be calibrated and of the compensation filter 66, said modeling circuit 80 being configured to serve The chosen model corresponds to an ideal compensation of the first channel 6 to be calibrated and the transfer function performed by the model is reduced to a predetermined predetermined time offset over the entire band of the traffic signal.
Thus, the temporal erasure device 36 is configured to coherently subtract an adapted replica from the reference calibration signal.
The digital circuits forming the injection device in part, and the compensation device in its entirety, and the temporal erasure device in their entirety are made for example by discrete digital circuits or integrated in one or more dedicated integrated circuits.
The digital circuits forming the injection device in part, and the compensation device in full, and the temporal erasure device in whole can be replaced by one or more programmable conventional electronic processors, the digital functions of the digital circuits being realized using software modules executed by the processor or processors.
According to FIG. 2 and a first embodiment, a dynamic calibration method 90 of a first radiofrequency analog reception channel 6 of a satellite payload, implemented by the dynamic calibration system 2 of FIG. a set of steps.
In a first step 92, a predetermined analog calibration signal, having a bandwidth less than or equal to the useful band of the first channel on which the calibration is performed, is injected at the input of the first RF channel 6 to be calibrated. The predetermined calibration signal is injected after being first generated by the digital generator 39 of a digital reference calibration signal over a frequency band, and then transposed in a compatible frequency band of the input band of the first RF channel to calibrate 6, with a power adjusted relative to that of a useful signal so as not to saturate the first output ADC analog-digital converter 18. Thus the calibration signal is superimposed on the useful traffic signal to form the first input upstream signal, as a composite signal, analog sum of the second signal and the third signal, and the first input upstream signal passes through all the functions of the first channel 6 to be calibrated 6 up to the port d input 70 of the compensation filter 66.
In a second step 94, executed in parallel with the first step 92, the temporal erasure device 36 builds a replica of the calibration signal from the reference calibration signal from the generator 39 and from a reference model 82, here digital, corresponding to the response of the first compensated RF chain, and having a transfer function consisting of a single predetermined constant delay.
Then in a third step 96, the digital subtracter 38 subtracts from the first composite output signal, outputted from the compensation filter 66 and forming the response of the first channel 6 compensated by the compensation filter 66 to the first input signal upstream composite, the replica of the calibration signal from the reference model 82, and thus erases the calibration signal injected into the first compensated composite signal.
Then, in a fourth step 98, the difference signal of the digital subtracter 38, taken from the measurement port 76, and the reference calibration signal, coming from the generator 39, serve to optimize the coefficients of the compensation filter 66, in order to to minimize the power of the difference signal. The optimization is carried out using the optimizer 68 included in the set formed by the optimizers using an adaptive processing, that is to say an iterative or recursive processing within a servo, and the optimizers using bulk processing of a set of bulk samples.
During the fourth step 98 and generally, the optimizer 68 configures, via the control port 78, a compensation actuator (a compensation filter 66 for Figure 1 or another device) from point measurements. 76, chosen as the measuring point, and the reference calibration signal from the generator 39 of the reference calibration signal. The algorithm used in the optimizer can operate in the time or frequency domain, iteratively / recursively or by block of samples. The algorithms used in the optimizer can be indifferently: Fourier Transform algorithms, least squares type algorithms such as LS, LMS or RLS algorithms or algorithms using covariances or correlations, for example algorithms of the type CMA.
Alternatively, the measuring point 76 is replaced by one of the points 70 and 72.
According to Figure 3 and a second embodiment of the invention, a dynamic calibration system 102 is shown for which the circuit to be calibrated 4 and the various elements of this circuit are identical to those of the circuit 4 of Figure 1 and are designated by the same reference numbers.
The dynamic calibration system 102 comprises: an injection device 132 for a second calibration signal whose waveform is known, arranged at the input and upstream of the first radio frequency channel to be calibrated 6, and whose architecture is identical or similar to that of the injection device 32 of Figure 1, and a compensation device 134 of the frequency and time response of the first radio frequency chain 6 to be calibrated on the useful band of the first channel 6, and a device temporal erasure 136 of the second injected calibration signal having a digital subtracter 138. Like the injection device 32 of FIG. 1, the injection device 132 is configured to inject the second calibration signal at a high level. , make it possible to optimize the accuracy of the estimation of the spectral and temporal response of the first channel to be calibrated, and make it possible to optimize the compen sation of the first channel 6 to be calibrated.
In practice, the power of the second calibration signal is dynamically adjusted relative to that of the third useful signal so as not to saturate the first output ADC analog-digital converter 18. The adjustment is for example carried out at the level of the digital generation 39 of FIG. calibration signal, the second analog channel 42 having a gain maintained constant, or at the second analog channel 42 by adjusting its gain. Like the dynamic calibration system 2 of FIG. 1, the frequency of the transposition signal of the first step-down transposition circuit 12 and of the second step-up transposition circuit 48 is identical, and the transposition signal is provided by the same oscillator. local 64, slaved to a reference master clock, not shown in Figure 3. Similarly, the sampling clocks of the analog-digital output converter 18 of the first channel 6, the digital-to-analog converter 40 input of the second analog channel 42, and the digital generator 39 of the second reference calibration signal are synchronized here preferably on the reference master clock.
In general, all analog-digital ADC and digital-to-analog converters DAC use one or more sampling clock signals derived from a common reference signal.
In a variant, the local oscillator signal OL used for the transpositions is neither identical nor derived from the same clock reference as the clock signal common to ADC and DAC analog-to-digital converters.
The compensation device 134 for the sequential and temporal response of the first radio frequency channel 6 to be calibrated here comprises an equalizer-type compensation filter 166 on the useful band of frequencies of the first analog channel 6 to be calibrated, to compensate for the disparities in amplitude. and in phase caused by the first analog channel 6 to be calibrated, and a calibration controller 168, configured to determine commands of the filter coefficients of the compensation filter 166.
The compensation filter 166 is disposed here directly downstream of the digital subtracter 138 of the temporal erasure device 136, the digital subtracter 138 being arranged directly downstream of the first analog channel 6 to be calibrated, at the output of the analog converter 18.
The compensation filter 166 has an input port 170, connected to the output port of the digital subtracter 138, and is configured to implement the compensation from filter coefficient setting commands of said compensation filter 166. The commands of adjustment are determined from several measurements of a fourth composite signal observed taken directly downstream of the first analog channel 6 to be calibrated to a measurement port 176 (s).
The calibration controller 168 is connected between the measurement port 176 (s) and a control port 178 of the compensation filter 166.
The calibration controller 168 is configured to receive one or more reference calibration signals from the digital generator 39, and to estimate characteristic parameters of the observed calibration signals of the time sequence from said reference calibration signals.
The calibration controller 168 is thus configured to determine the spectral response of the first analog channel 6 to be calibrated from the estimates of the second calibration signals measured at the port 176, then to calculate the response of the compensation filter 166, and then to determine the coefficients associated for the compensation filter.
The temporal erasure device 136 comprises the digital generator 39 of the sequence of the second digital reference calibration signals shared with the injection device 132, the calibration controller 168, the digital subtracter 138, and a third digital channel 182. for supplying replicas of the reference calibration signals of the sequence to be subtracted, adapted in terms of a compatible transposition frequency from the output frequency of the radio frequency chain 6 to be calibrated, of gains and delays respectively compatible with the gains and the times propagation of the second calibration signals along the propagation path traversing successively, the injection device 132 and the first radio frequency chain 6 to be calibrated.
Here, the third digital channel 182 comprises the calibration controller 168 serving as an estimator of the characteristic parameters of the calibration signals observed after the first analog channel 6 to be calibrated corresponding to the time sequence of the second calibration signals, and a generator 184 of replicas , adapted to the second calibration signals observed, and to subtract.
Thus, the temporal erasure device 136 is configured to coherently subtract the adapted replicas of the reference calibration signals from the time sequence at the output of the first analog channel 6 to be calibrated.
The digital circuits forming the injection device in part, and the compensation device in its entirety, and the temporal erasure device in their entirety are made for example by discrete digital circuits or integrated in one or more dedicated integrated circuits.
The digital circuits forming the injection device in part, and the compensation device in full, and the temporal erasure device in whole can be replaced by one or more programmable conventional electronic processors, the digital functions of the digital circuits being realized using software modules executed by the processor or processors.
According to FIG. 4 and a second embodiment, a dynamic calibration method 190 of a first radiofrequency analog reception channel 6 of a satellite payload, implemented by the dynamic calibration system 102 of FIG. 3, comprises a set of steps.
In a first step 192, a second predetermined analog calibration signal, having a bandwidth less than or equal to the useful band of the first channel 6 on which the calibration is performed, is injected at the input of the first RF channel 6 to be calibrated. , most often after an antenna source. The second predetermined calibration signal is injected after being generated by the digital reference generator 39 and transposed to a compatible carrier frequency of the input band of the first RF channel 6 to be calibrated, with dynamically adjusted power relative to that of FIG. a third signal useful in order not to saturate the first output ADC analog-digital converter 18. Thus the calibration signal is superimposed on the useful traffic signal to form the first input upstream signal, as a composite signal analog sum of the second signal and the third signal, and the first input upstream signal passes through all functions of the first channel 6 to be calibrated to the input port 170 of the compensation filter 166.
In a second step 194, executed in parallel with the first step 192, the calibration controller 168 estimates, from the measurement of the first output signal of the first channel 6 and the second calibration signal, from the digital generator 39 , the parameters characterizing the deformation of the second calibration signal such as the gain, the delay, the phase, said parameters making it possible to define a compensation for different frequencies of the frequency response of the first analog channel 6 to be calibrated.
Then in a third step 196, the generator 184 of adapted replicas builds for each second observed calibration signal of the sequence, a local replica of the calibration signal from the estimated parameters (gain, delay, phase) provided by the calibration controller. 168.
Then in a fourth step 198, the digital subtracter 138 subtracts the adapted replica of the calibration signal from the first output downstream signal, in order to propagate only the useful traffic signal.
Then, in a fifth step 200, the calibration controller 168 updates a function for correcting the spectral response of the first analog channel 6 on the useful band of the first channel to be calibrated from the estimated deviations between the second calibration signals. , extracts of the fourth composite signal observed, and the corresponding reference calibration signals, the correction function being implemented by the compensation filter 166.
The digital subtracter 138 erases the measurement signal of the composite signal, subtracting the adapted replica, defined by the estimated parameters, and generated by the adapted digital replica generator 184 parameterized using the controller 168, the fourth signal observed at measurement port 176, connected here to the first output port downstream of the first channel.
At the output of the digital subtracter 138, the signal carries only the traffic, as if the calibration or measurement signal had not been injected.
The defects of the frequency response of the first reception channel 6 are corrected by the compensation filter 166 in a compensation function whose filter coefficients have been calculated by the calibration controller 168.
The solutions proposed in the first and second embodiments of the dynamic calibration systems and methods, described in FIGS. 1 to 4, each allow a precise and rapid estimation of the defects of the first RF channel as a function of frequency, thanks to a measurement signal with frequency support of any width and high level, which improves the accuracy and speed of measurement of the amplitude / phase defects of the first chain, this over the entire useful band, and this without interruption of service and degradation of the RF signal useful for users.
According to Figure 5 and a third embodiment of the invention, a dynamic calibration system 202 of an RF radio frequency circuit 204 to be calibrated of a satellite payload is shown.
The RF radio frequency circuit 204 comprises an analog RF radio frequency channel 206, forming a first channel to be calibrated on a useful band of the string. Here, the first analog channel 206 is an analog chain of a communication transmitter, between upstream a first upstream port 208 receiving a first digital input signal and downstream a first downstream port 210 providing a a first analog output signal.
The first analog output signal is the frequency and time response of the first analog channel 206 to be calibrated at the first input upstream signal.
The first analog radio frequency channel 206 to be calibrated comprises a first frequency upshift transposition circuit 212, a first upstream amplification stage 214, arranged upstream of the first transposition circuit 212, a downstream first amplification stage 216, disposed downstream. the first transposition circuit 212, and a first input digital-to-analog converter 218 whose input port is connected to the first upstream port 208 of the first radio frequency channel 206 to be calibrated. The direction from upstream to downstream is represented by an arrow 220 oriented from the RF input port 222 to the RF output port 224 of the upshift transposition circuit 212.
In general, the first radio frequency channel to be calibrated may contain any number of amplifiers and / or filters, greater than or equal to one, and not necessarily limited to two amplifiers.
As a variant, the first radio frequency channel to be calibrated may be devoid of frequency transposition by mixer and local oscillator. The automatic calibration system 202 comprises: an injection device 232 for a second digital calibration signal whose waveform is known, arranged at the input and upstream of the first radio frequency channel to be calibrated 206, and a compensation device 234 for the frequency and time response of the first radio frequency channel 206 to be calibrated on the useful band of the first channel 206, and a temporal erasure device 236 for the second injected calibration signal having an analog subtractor. 238.
The injection device 232 of the second calibration signal comprises, put in series, a digital generator 240 of a digital reference calibration signal, and a second digital injection chain 242, here limited to a digital summator 244 of two digital signals, connected to said digital generator 240, the two digital signals being formed by a third input useful signal and the second calibration signal injected.
The second calibration signal has a useful bandwidth less than or equal to the useful bandwidth of the first string to be calibrated.
The injection device 232 is here configured to inject the second calibration signal which has the same waveform as the reference calibration signal, generated by the digital generator 240 of the reference calibration signal.
This injection takes place through the digital summator 244 which includes a first injection input port 256, a second injection input port 258, connected downstream of and to the digital output of the digital generator 240, and a third injection output port 260, connected to the input port 208 of the first channel to be calibrated 206 through a digital compensation filter 266 of the first channel 206 to be calibrated.
The first injection input port 256 is configured to receive the third input useful signal, for example a communication useful traffic signal, designated Su (t), while the second injection input port. 258 is configured to receive the calibration signal, designated Scai (t) and outputted from the digital generator 240.
The third injection output port 260 is configured to supply the input of the digital compensation filter 266 with the input signal Su (t) + Scai (t) equal to the time sum of the traffic signal Su (t) and the Scai calibration signal (t) ·
The injection device 232 is configured to inject the second calibration signal at a high level, to make it possible to optimize the accuracy of the estimation of the spectral and temporal response of the first channel to be calibrated, and to make it possible to optimize the compensation of the first channel to be calibrated.
In practice, the power of the second calibration signal is dynamically adjusted relative to that of the third useful signal so as not to saturate the first digital-to-analog converter DAC 218. The adjustment is made at the digital generator 240.
The compensation device 234 of the frequency and frequency response of the first radio frequency channel 206 to be calibrated comprises the compensation filter 266 on the useful frequency band of the first analog channel 206 to calibrate amplitude and phase disparities caused by the first analog channel 206 to be calibrated, an optimizer 268 of the coefficients of the compensation filter 266, and a fourth chain of measurements 270.
The digital compensation filter 266 is disposed directly upstream of the first radio frequency channel 206 to be calibrated and directly downstream of the digital summator 244 of the injection device 232.
The digital compensation filter 266 includes an input port 272 connected to the output port 260 of the digital summator 244 and a downstream output port 274 connected to the first upstream port 208 of the first channel 206 to be calibrated.
The compensation filter 266 is configured to implement the compensation from filter coefficient commands of said filter 266, the commands being determined from measurements of a fourth observed analog signal, taken directly downstream of the analog subtractor 238. a measurement port 276 (s). The optimizer 268 is here an optimizer using an adaptive processing, that is to say iterative or recursive processing within a servocontrol, or using a block processing of a set of samples measured in block, connected indirectly downstream to the measurement port 276 (s) through the fourth measurement chain 270 and directly upstream to a control port 278 of the compensation filter 266. The optimizer 268 is configured to determine the commands of the coefficients of the compensation filter 266 from a set of measurements of the fourth observed signal, taken directly downstream of the analog subtractor 238 at the measurement port 276, and from the second reference calibration signal coming from the 240 digital generator.
In general and according to various variants, the adaptive or block optimizer 268 can operate iteratively or in block, according to the optimization algorithm used. The objective of the optimizer is to configure, via the control port 278, a compensation actuator (a compensation filter 266 for Figure 5 or another device) from measurements of the point 276, chosen as the measuring point , and the reference calibration signal from the generator 240 of the reference calibration signal. Thus the optimizer comprises a second input terminal for receiving the reference calibration signal from the generator 240 of the calibration signal. The algorithm used in the optimizer can operate in the time or frequency domain, iteratively / recursively or in block. The algorithms used in the optimizer can be indifferently: Fourier Transform algorithms, least squares type algorithms such as LS, LMS, RLS algorithms, algorithms using covariances or correlations, CMA type algorithms.
The fourth measurement chain 270 is an analog signal routing chain of the fourth observed signal, taken directly downstream of the analog subtractor 238, up to the digital adaptive optimizer 268.
The fourth analog measurement chain 270 comprises, upstream, a measurement coupler 282 with an input channel, connected to the measurement taking port 276, and two output channels including a measurement extraction channel connected to a measurement port 284.
The fourth analog measurement chain 270 includes a fourth frequency downconverter circuit 286, a fourth upstream amplifier stage 288 arranged upstream of the fourth downconverter circuit 286 and connected at input to the measurement port 284, a fourth downstream stage. amplification circuit 290 arranged downstream of the fourth downconverter circuit 286, and an analog-digital output converter 292 disposed at the downstream end of the measurement chain 270.
The temporal erasure device 236 comprises the digital generator 240 of the digital reference calibration signal shared with the injection device 232, the analog subtractor 238, and a third digital-analog hybrid chain 300 for supplying a replica of the reference calibration signal to be subtracted, adapted in terms of a compatible transposition frequency of the output frequency of the radio frequency channel 206 to be calibrated and a compatible delay of the propagation times of the signal along the successively traversing propagation path the first radio frequency channel 206 to be calibrated and the compensation filter 266.
Here, the third digital-analog hybrid chain 300 comprises, put in series, a third digital sub-string 302 and a third analog sub-string 304.
The third digital subchain 302 includes in series a digital reproduction circuit 306 of a digital reference model of a time and frequency response of the first radio frequency channel 206 and the compensation filter 266 of the first channel 206 when the filter compensation 266 is optimized, and correction amplitude and phase dispersions caused by the third analog subchannel 304, and a third digital-to-analog converter 308.
The third analog subchain 304 comprises a third frequency-increasing transposition circuit 312, a third upstream amplification stage 314, arranged upstream of the third transposition circuit 312, a third downstream power-amplification stage 316, disposed in downstream of the third transposition circuit 312, and a measurement coupler 318, connected between the third downstream stage 316 and the analog subtractor 238, and whose measurement ratio line 320 is connected to a first input port 322 of a switch 324 with two inputs 322, 326 and an output 328.
The switch 324, connected between, on the one hand, the input terminal 284 of the measurement coupler 282 through its second input port 326, and on the other hand the input of the fourth upstream amplification stage 288 to the through its output port 328, is configured to selectively repatriate on command measurements taken among measurements at the output of the first analog channel 206 to be calibrated and measurements at the output of the third analog sub-channel 304. It should be noted that the reproduction circuit 306 of a digital reference model is configured to receive commands for correcting the time and frequency response of the third analog sub-channel 304, said correction commands being determined by the digital adaptive optimizer 268, and the measurement measuring chain 270 being assumed to be calibrated and not to affect the measurements made in the measurement 276.
The analog subtractor 238 is here a device comprised in the assembly formed by the hybrid couplers 180 ^^ and the hybrid ring couplers, each of these devices being configured to perform the combination in opposition of the first output signal of the first channel. calibrate 206 and the hybrid chain output signal 300.
As a variant, the erasing device 236 performs the subtraction of the calibration signal from a coupler producing the in-phase combination of the first signal at the output of the first channel to be calibrated 206 and the signal at the output of the hybrid chain 300. one of these signals being previously inverted either in one of the compensation filters (266 or 306), or at the level of the signal generator 240, or by a phase shift of 180 ° of the local oscillator OL signal at the input of one of the circuits frequency conversion 212 or 312.
Here, the frequencies of the transposition signals of the first elevator transposition circuit 212 as the transposition circuit of the first channel, the third elevator transposition circuit 312 as the transposition circuit of the third channel, and the fourth transposition circuit. step-down 286 as a transposition circuit of the fourth channel are identical and a common transposition signal is provided by the same shared local oscillator 322, slaved to a reference master clock, not shown in FIG. sampling of the analog-to-digital converter 292, the digital to analog converters 218, 308, and the digital generator 240 of the reference calibration signal are synchronized to the reference master clock.
In general, all the mixers of the different channels use the same local oscillator OL signal, with a phase shift, to carry out the transpositions of rising or falling frequencies.
In general, all analog-digital ADC and digital-to-analog converters DAC use one or more sampling clock signals derived from a common reference signal.
In a variant, the local oscillator signal OL used for the transpositions is neither identical nor derived from the same clock reference as the clock signal common to ADC and DAC analog-to-digital converters.
As a variant, the first, third, and fourth channels have no frequency transposition circuits.
The configuration of the time-clearing device 236 of FIG. 5 thus makes it possible to coherently subtract from the first output signal of the first channel 206 to calibrate an adapted replica of the reference calibration signal.
The digital circuits forming the injection device in its entirety, and the compensation device in part, and the temporal erasure device in part are made for example by discrete digital circuits or integrated into one or more dedicated integrated circuits.
The digital circuits forming the injection device in its entirety, and the compensation device in part, and the temporal erasure device in part can be replaced by one or more conventional programmable electronic processors, the digital functions of the digital circuits being realized at using software modules executed by the processor or processors.
According to FIG. 6 and a third embodiment, a dynamic calibration method 350 of a first radiofrequency analog transmission channel 206 of a satellite payload, implemented by the dynamic calibration system 202 of FIG. , includes a set of steps.
In a first step 352, a predetermined digital calibration signal, having a bandwidth less than or equal to the useful band of the first string on which the calibration is performed, is injected at the input of the digital compensation filter 266, preceding the first RF channel 206 to be calibrated. The predetermined calibration signal is generated by the digital generator 240 of a reference calibration signal in a frequency band included in and compatible with the input band of the first analog channel 206 to be calibrated, and added numerically to the signal of useful traffic to form a first input upstream composite signal. The power of the injected calibration signal is adjusted relative to that of the useful traffic signal in order not to saturate the first DAC 218 digital-to-analog converter. The first input upstream composite signal then passes through all the functions of the first channel 206 to calibrate to the first downstream output port 210.
In a second step 354, executed in parallel with the first step 352, the temporal erasure device 236 builds a replica of the calibration signal from the reference calibration signal and a reference model 306, here digital, corresponding to the response of the first compensated RF channel and the correction of the response of the third analog sub-channel 304 for amplifying and transposing the time-clearing device 236. The transfer function of the response of the first compensated RF channel consists of a simple constant predetermined delay over the entire useful band of the first string.
Then in a third step 356, the analog subtractor 238 subtracts from the output composite signal 210 of the first transmission analog channel 206 as a response signal to the first composite signal of the first channel 206 compensated by the compensation filter 266, the replica of the calibration signal from the reproduction circuit 306 and transposed to the output frequency of the first transmission chain 206, and thus erases the injected calibration signal of the compensated composite signal.
Then, in a fourth step 358, a portion of the difference signal of the analog subtractor 238, taken as a measurement signal at the measurement taking port 276 by means of the analog coupler 282, and the reference calibration signal from the digital generator 240. are used to optimize the coefficients of the compensation filter 266 on the first channel to be calibrated 206, in order to minimize the power of the difference signal. The optimization is carried out using the optimizer 268 included in the set formed by the optimizers using an adaptive processing, that is to say an iterative or recursive processing within a servo, and the optimizers using a block processing of a set of measures.
During the fourth step 358 and more generally, the optimizer 268 configures, via a first control port, a compensation actuator (the compensation filter 266 for Figure 1 or another device) from measurements of the point 276, chosen as the measuring point and the reference calibration signal from the generator 240 of the reference calibration signal. The algorithm used by the optimizer can operate in the time or frequency domain, iteratively / recursively or by block of samples. The algorithms used in the optimizer can be indifferently: Fourier Transform algorithms, least squares type algorithms such as LS, LMS or RLS algorithms or algorithms using covariances or correlations, for example algorithms of the type CMA. The optimizer 268 also configures via a second control port, the reproduction circuit 306 of a calibration signal adapted for the erase function from measurements of the point 276, chosen as the measurement point and the reference calibration signal from of the generator 240 of the reference calibration signal.
For developing the commands of the compensation filter 266 and the reproduction circuit 306 of a suitable replica, the optimizer takes into account the transfer function of the first channel to be calibrated compensated by the compensation filter and the fourth channel. of measures, put in series.
The difference signal observed at the output of the analog subtractor 238 and in the steady state, that is to say when the calibration or the compensation has converged, corresponds to the traffic signal alone after elimination or erasure of the calibration signal.
In the same fourth step 358, the measurement signal can also be used to correct the amplitude and phase dispersions caused by the third analog substructure 304 to the erase signal.
The solution proposed in the third embodiment of the dynamic calibration system and method, described in FIGS. 5 and 6, allows a precise and rapid estimation of the defects of the first RF channel to be calibrated, by means of a calibration signal having a level high input injection of the first chain, which improves the accuracy and speed of measurement of the amplitude / phase defects of the first chain, this over the entire useful band of the first chain, and this without interruption of service and degradation RF signal useful for users.
In general and independently of the transmitter or receiver structure of the first channel to be calibrated, when the compensation of the first channel to be calibrated is not ideal, the useful signal as well as the calibration signal are distorted.
At the output of the first channel to be calibrated, the distorted calibration signal superimposed on the distorted useful signal does not correspond to the replica of the reference calibration signal, the erasure is imperfect after the subtractor 38 in FIG. 1, 238 in FIG. 138 in Figure 3, and there remains a calibration signal residue superimposed on the useful signal.
Thus, the useful signal at the output of the channel to be calibrated and after subtraction is doubly affected by the distortions of the first chain that is insufficiently compensated and by the residual of the calibration signal that is insufficiently erased. The erasure may be imperfect if the erase replica is insufficiently adjusted to the multiplex signal at the output of the first string to be calibrated. This is the case in the absence of precise prior knowledge of the spectral and temporal response of the first channel to be calibrated, either at startup or because of a significant change in the response of the chain between two calibrations.
In the case where the erasure is imperfect, the residual calibration signal constitutes a source of interference for the useful signal.
In order to limit the interference of the calibration signal residue with the useful signal in the case mentioned, one solution consists in iterating several calibration cycles by progressively increasing the power of the calibration signal injected upstream of the first channel to be calibrated. Each new cycle makes it possible to improve the knowledge of the spectral and temporal response of the first channel, and makes it possible to improve its compensation, and indirectly makes it possible to better match the calibration signal at the output of the chain with the replica of the calibration signal of reference, to finally optimize the quality of the erasure of the calibration signal at the output of the first channel.
Subsequently, when the knowledge of the spectral and temporal response of the first chain is acquired and considered stable, the optimizer 68, 168, 268 can perform a faster periodic calibration by injecting the calibration signal directly on a high level, to have a good calculation accuracy of the compensation, while ensuring the absence of saturation of the analog digital converter, designated by the reference numeral 18 in Figures 1 and 3 for a chain in reception, and designated by the reference numeral 292 for a channel in emission.
In general, a dynamic calibration system according to the invention makes it possible to calibrate a radio frequency circuit of a satellite payload comprising one or more first receiver chains, and / or one or more transmitter chains.
The previous calibration devices, described in FIGS. 1, 3 and 5, are generalizable to calibrate in sequence a set of an integer number N of first analog channels by pooling certain hardware and software resources, in order to limit the material complexity, the consumption electric.
In the case of analog reception-type channels as illustrated in FIGS. 1 and 3, the injection channel 32, 132 is shared for all the N reception channels to be calibrated. The analog calibration signal is injected at the input of all the channels to be calibrated either simultaneously with a divider 1: N (in English "splitter"), or sequentially with a switching matrix 1: N, these elements being connected upstream couplers 44.
In the case of analogue transmission-type chains as illustrated in FIG. 5, the replica chain of the time-clearing device 236 as well as the measurement chain of the compensation device 234 are pooled for all the N-channels of FIG. issue to be calibrated.
The reference analog calibration signal adapted for subtraction is injected at the output of all the N channels to be calibrated either simultaneously with a 1: N divider, or sequentially with a 1: N switching matrix, these elements being connected upstream of the N channels. couplers 238.
The analog measurement signal at the output of the couplers 284 is selected by an N: 1 switching matrix connected downstream of the couplers 284 and upstream of the measurement chain 234.
According to FIG. 7 and a fourth embodiment, a dynamic calibration system 402 of a set of first two analog channels to be calibrated for transmission 404, 406 comprises a replica chain 412 of the calibration or reference signal, shared at first and second time clearing devices 424, 426 associated respectively with the first first analog channel 404 and the second first analog channel 406.
The dynamic calibration system 402 also comprises a measurement chain 432 shared with first and second compensation devices 434, 436, respectively associated with the first first analog channel 404 and the second first analog channel 406.
The dynamic calibration system 402 here comprises first and second injection summers 444, 446 respectively connected upstream of first and second compensation filters 454, 456, themselves respectively connected upstream of first and second digital-to-analog converters. 464, 466, the first digital-to-analog converter 464 and the second digital-to-analog converter 466 respectively forming an input of the first analog channel 404 and an input of the second first analog channel 406.
The dynamic calibration system 402 comprises a switch network 472 (in English "switches") configured to selectively route calibration replica signals from the pooled replica chain to a first analog subtractor 474 and a second analog subtractor 476, and for selectively routing output measurement signals of the first first and second analog channels to be calibrated from a first analog coupler 484 and a second analog sampling coupler 486 to the shared measurement string 432.
The first analog subtractor 474 and the first analog sampling coupler 484 are connected together and at the output of the first channel to be calibrated 404, whereas the second analog subtractor 476 and the second analog sampling coupler 486 are connected together and at the output of the second chain to calibrate 406.
In general terms, a first radio frequency channel to be calibrated is an analog amplification and filtering chain with or without transposition at a predetermined transposition frequency of a first input signal, formed by the time sum of a second signal. calibration and a third input useful signal.
The first radio frequency channel to be calibrated on a useful band of channel is between upstream a first upstream port of reception of the first input signal and downstream a first downstream port of supply of the first output signal, the first output signal being the frequency and time response of the radio frequency channel to be calibrated at the first input signal.
In general, the automatic calibration system comprises: a device for injecting a second calibration signal whose waveform is predetermined upstream of the radio frequency channel to be calibrated, the second calibration signal being injected directly in digital form or indirectly in analog form through a second analog injection chain from a reference calibration signal; a device for compensating the frequency and frequency response of the first radio frequency channel to be calibrated, comprising a compensation filter on the useful frequency band of the first channel to be calibrated, the compensation filter being disposed upstream or downstream of the first radiofrequency channel to be calibrated and the compensation being made from measurements of a fourth signal, observed downstream of the first radio frequency channel to be calibrated and the compensation filter, or directly downstream of the first channel to be calibrated; a device for temporally erasing the injected calibration signal having an analog or digital subtractor connected downstream of the first radio frequency channel to be calibrated.
The analog or digital subtractor can be connected directly downstream of the first radio frequency channel to be calibrated or downstream of the compensation filter.
The digital subtracter can be connected directly between upstream the first channel to be calibrated and downstream the compensation filter.
In general, the temporal erasure device also comprises a third digital or analog supply chain of a replica of the reference calibration signal to be subtracted.
The replica is adapted in terms of the frequency of compatible transposition of the output frequency of the radio frequency channel to be calibrated, of the compatible delay of the propagation times of the signal through the injection device and the first radio frequency channel to be calibrated or through the injection device, the first radio frequency channel to be calibrated and the compensation filter.
The time-erase device is configured to coherently subtract the adapted replica of the reference calibration signal from the output signal of the first radio frequency channel to be calibrated to minimize the residual of the output calibration signal.
According to Figs. 8A and 8B, a first general method 560 and a second general method 562 for dynamic calibration of a radio frequency circuit of a satellite payload include the calibration methods of Figs. 2, 4 and 6.
The radio frequency circuit to be calibrated, for example that of a receiver or transmitter, comprises a first radio frequency channel to be calibrated for amplification and filtering and for transposition at a predetermined transposition frequency of a first input signal formed. by the time sum of a second calibration signal and a third input useful signal.
The first radio frequency channel to be calibrated on a useful band of channel is between upstream a first upstream port of reception of the first input signal and downstream a first downstream port of supply of a first output signal, the first signal of output being the frequency and time response of the first radio frequency channel to be calibrated at the first input upstream signal.
The first and second general methods 560, 562 comprise a set of steps.
In a first step 564, an injection device injects a second calibration signal whose waveform is predetermined upstream of the first radio frequency channel to be calibrated, the second calibration signal being directly injected in digital form or indirectly in the form of analog through a second analog injection chain from a reference calibration signal.
Then in a second step 566, a compensation device compensates, on the useful band of frequencies of the first string, amplitude and phase disparities caused by the first string to be calibrated, using a compensation filter, disposed upstream or downstream of the first radio frequency channel to be calibrated, the compensation being made from measurements of a fourth signal, observed downstream of the first radio frequency channel to be calibrated and the compensation filter, or directly downstream of the first channel to calibrate.
In a third step 568, executed after the first step 564, a temporal erasure device temporally erases the injected calibration signal using an analog or digital subtractor connected downstream of the first channel to be calibrated.
According to Figure 8A and the first configuration 560 of the general dynamic calibration method, the third step 568 is executed after the second step 566.
This first configuration is implemented for example in the following two cases.
In a first case, the first channel to be calibrated is the chain of a transmitter, the subtractor is an analog subtractor connected directly downstream of the first channel to be calibrated, and the compensation filter is a digital compensation filter arranged upstream. of the radio frequency chain to be calibrated.
In a second case, the first channel to be calibrated is the chain of a receiver, the subtractor is a digital subtractor connected directly downstream of the compensation filter, and the compensation filter is a digital compensation filter arranged directly downstream. of the first chain to calibrate.
According to Figure 8B and the second configuration 562 of the general dynamic calibration method, the third step 568 is executed before the second step 566.
This second configuration is implemented for example in the case where the first channel to be calibrated is the chain of a receiver, the subtractor is a digital subtractor connected directly upstream between the first channel to be calibrated and downstream the compensation filter. , and the compensation filter is a digital compensation filter, arranged directly downstream of the digital subtracter.
The system and the dynamic calibration method are designed to be activated and to operate permanently, repeatedly, periodically or periodically, or on demand by sending remotes from the ground, for example.

权利要求:
Claims (17)
[1" id="c-fr-0001]
1. A system for dynamically calibrating a radio frequency circuit of a satellite payload, the RF radio frequency circuit (4; 204) comprising a first radio frequency chain (6; 206) to be calibrated for amplification and filtering with or without transposition. at a predetermined transposition frequency of a first input signal formed by the time sum of a second calibration signal and a third input useful signal, the first radio frequency channel (6; 206) to be calibrated on a first input signal; useful chain band being between upstream a first upstream port (8; 208) receiving the first input signal and downstream a first downstream port (10; 210) providing a first output signal, the first output signal being the frequency and frequency response of the radio frequency chain (6; 206) to be calibrated at the first input signal; and the automatic calibration system comprising: an injection device (32; 132; 232) of the second calibration signal whose waveform is predetermined upstream of the first radio frequency chain (6; 206) to be calibrated; a calibration signal being directly injected in digital form or indirectly in analog form through a second analog injection chain (42) from a reference calibration signal, and the band of the second calibration signal being included in useful band of the first channel to be calibrated: and a compensation device (34; 134; 234) of the frequency and frequency response of the first radio frequency channel (6; 206) to be calibrated, comprising a compensation filter (66; 166; 266) on the useful frequency band of the first chain (6; 206) to be calibrated, the compensation filter (66; 166; 266) being disposed upstream or downstream of the first cell. a radio frequency (6; 206) to be calibrated and the compensation being made from measurements of a fourth signal, observed downstream of the first radio frequency channel (6; 206) to be calibrated and the compensation filter (66; 266), or directly downstream of the first chain (6) to be calibrated; the automatic calibration system being characterized in that it comprises a temporal erasing device (36; 136; 236) of the second injected calibration signal having an analog or digital subtractor (38: 138; 238) connected downstream of the first radio frequency chain (6; 206) to be calibrated.
[2" id="c-fr-0002]
A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 1, wherein the analog or digital subtractor (38; 238) is connected downstream of the first radio frequency channel (6; 206) to calibrating and downstream of the compensation filter (66; 266), or the digital subtracter (138) is connected upstream of the first radio frequency chain (6) to be calibrated and downstream of the compensation filter (166).
[3" id="c-fr-0003]
3. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 2, wherein the temporal erasing device (36; 136; 236) also comprises a third digital channel. or analog (80; 182; 304) for providing a replica of the reference calibration signal to be subtracted, adapted in terms of compatible transposition frequency of the output frequency of the radio frequency channel (6; 206) to be calibrated, of compatible delay of the propagation time of the signal through the injection device (32; 132; 232) and the first radiofrequency channel (6; 206) to be calibrated, or through the injection device, of the first radiofrequency channel calibrating and compensating filter (66; 266); and the time erasing device (36; 136; 236) is configured to coherently subtract the adapted replica of the reference calibration signal from the output signal of the first radio frequency channel (6; 206) to be calibrated.
[4" id="c-fr-0004]
A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 3, further comprising a first generator of one or more local oscillator signals OL (64; ) identical to a phase shift and synchronized to a first reference clock; and wherein when the first radio frequency channel to be calibrated comprises one or more frequency transposition circuits; and / or when the second injection channel is analogue and comprises one or more frequency transposition circuits; and / or when the third supply chain of the adapted replica is analogue and comprises one or more frequency transposition circuits, the first transposition circuit or circuits, and / or the second or the second transposition circuit, and / or the the third transposition circuits are configured to use the same local oscillator LO signal (64; 322) at a phase shift and perform up- or down-frequency transpositions.
[5" id="c-fr-0005]
5. A dynamic calibration system of a radio frequency circuit of a satellite payload according to any one of claims 1 to 4 wherein when the injection of the calibration signal is digital, the injection device (232) of the calibration signal comprises a digital generator of a digital reference calibration signal (240) and a digital summator (244) of the reference calibration signal to a digital traffic signal, and when the injection of the calibration signal is analog the injection device (32; 132) of the calibration signal comprises a digital generator (39) of a digital reference calibration signal, a digital-to-analog converter (40), and a second analog injection channel including an analog coupler (44) operating as a summator of two analog signals, and the injection device (32; 132; 232) of the calibration signal is configured to adjust bending the power of the second calibration signal dynamically relative to that of the third useful signal to the highest possible compatible level of no saturation of an analog-to-digital or digital-to-analog converter of the first radio frequency channel (6; 206) to be calibrated respectively at the outlet or at the inlet of said first chain (6; 206).
[6" id="c-fr-0006]
6. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 5, wherein, the first radio frequency channel (6) to be calibrated is an analog channel of a receiver. communication comprising a first frequency down-converting circuit (12), a first upstream amplification stage (14) arranged upstream of the first transposition circuit (12), a first downstream amplification stage (16) disposed downstream of the first transposition circuit (12), and a first output analog-to-digital converter (18) connected at the output of the first channel (6) to be calibrated; and the injection device (32) of the calibration signal includes, in series, a digital generator (39) of a digital reference calibration signal, a digital-to-analog converter (40), and a second channel of analog injection (42) including an analog coupler (44) operating as a summator of two analog signals; and the injection device (32) is configured to inject one or more calibration signals of a time sequence covering the useful frequency band over which the first chain (6) is to be calibrated, and to add the calibration signal (s). the third useful traffic signal; and the time erasing device (36) comprises the digital generator (39) of the digital reference calibration signal shared with the injection device (32), a digital subtracter (38), and a third digital channel (80). ) of providing a replica of the reference calibration signal to be subtracted, adapted in terms of a compatible transposition frequency of the output frequency of the radio frequency channel to be calibrated and a compatible delay of the signal propagation delays the along the path of propagation successively traversing the injection device (32), the first radiofrequency channel (6) to be calibrated and the compensation filter (66).
[7" id="c-fr-0007]
7. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 6, wherein, the compensation device (34) of the frequency and time response of the first radiofrequency channel (6) to be calibrated, comprises a compensation filter (66) and an adaptive or bulk optimizer (68) of the coefficients of the compensation filter (66), the compensation filter (66) being arranged directly downstream of the first radio frequency channel (6) to be calibrated and directly upstream of the digital subtractor (38) of the time-out device (36), and the adaptive optimizer (68) is configured to determine commands of the compensation filter coefficients (66) from measurements of a fourth signal observed, taken directly downstream of the digital subtracter (38), and from the reference calibration signal from the reference generator (39).
[8" id="c-fr-0008]
8. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 5, wherein, the first radio frequency channel (6) to be calibrated is an analog channel of a receiver of communication comprising a first frequency down-converting circuit (12), a first upstream amplification stage (14) arranged upstream of the first transposition circuit (12), a first downstream amplification stage (16) disposed downstream of the first transposition circuit (12), first transposition circuit (12), and a first output analog-to-digital converter (18) connected at the output of the first channel (6) to be calibrated; and the injection device (132) of the calibration signal includes, in series, the digital generator (39) of a digital reference calibration signal, the digital-analog converter (40), and a second channel of analog injection (42) including an analog coupler (44) operating as a summator of two analog signals; and the injection device (132) is configured to inject one or more calibration signals of a time sequence covering the useful frequency band over which the first channel (6) is calibrated, and to add the one or more calibration signals to third useful traffic signal; and the time erasing device (136) comprises the digital generator (39) of the digital reference calibration signals of the time sequence shared with the injection device (132), the digital subtracter (138), and a third digital chain (182) for supplying replicas of the reference calibration signals of the sequence to be subtracted, adapted in terms of a compatible transposition frequency of the output frequency of the radio frequency channel to be calibrated, of compatible gains and delays, respectively gains and propagation times of the calibration signals along the propagation path successively traversing the injection device (132) and the first radiofrequency channel (6) to be calibrated.
[9" id="c-fr-0009]
A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 8, wherein the third digital channel (182) comprises: the calibration controller (168) configured to estimate characteristic parameters of the calibrating the time sequence from the fourth observed current signal, and configured to determine characteristic parameters of replicas adapted to the sequence calibration signals from the calibration signals of the sequence generated by the calibration signal generator (39) reference and estimated characteristic parameters; and a digital generator (184) of the replicas adapted to the observed calibration signals and to be subtracted.
[10" id="c-fr-0010]
10. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 8, wherein, the compensation device (134) of the frequency and time response of the first radio frequency channel (6) to be calibrated, comprises a compensation filter (166) and a control circuit (168) of the coefficients of the compensation filter (166), the compensation filter (166) being connected directly downstream of the digital subtracter (138), said subtractor (138) being disposed directly downstream of the first radio frequency chain (6) to be calibrated; and the control circuit (168) being configured to determine commands of the compensation filter coefficients (166) from a plurality of measurements of a fourth observed signal taken directly downstream of the first channel to be calibrated (6) and from the reference calibration signal from the reference generator (39).
[11" id="c-fr-0011]
11. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 5, wherein, the first radio frequency channel (206) to be calibrated is an analog channel of a transmitter. communication device comprising a first frequency-increasing transposition circuit (212), a first amplification-upstream stage (214) arranged upstream of the first transposition circuit, a first amplification-downstream stage (216) disposed downstream of the first amplification circuit transposition (212), and a first input digital-to-analog converter (218), connected at the output of the compensation filter (266); the injection device (232) of the calibration signal includes, in series, a digital generator (240) of a digital reference calibration signal, and a second digital injection chain (242) comprising a digital summator ( 244) of two digital signals; and the time erasing device (236) comprises the digital generator (240) of the digital reference calibration signal shared with the injection device (232), the analog subtractor (238), and a third digital hybrid channel. analog circuit (300) for providing a replica of the reference calibration signal to be subtracted, adapted in terms of a compatible transposition frequency of the output frequency of the first radio frequency channel to be calibrated and a compatible delay of the propagation of the signal along the propagation path successively traversing the injection device (232), the compensation filter (266) and the first radiofrequency channel (206) to be calibrated.
[12" id="c-fr-0012]
A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 11, wherein the third hybrid channel (300) includes serializing a third digital sub-string (302) and a third sub-string. analog channel (304), the third digital subchain (302) including in series: a digital circuit (306) for reproducing a numerical reference model of a time and frequency response of the first radio frequency channel (206) and of the compensation filter (266) of the first string when the compensation performed by the compensation filter (266) is optimal, and of the correction of the amplitude and phase dispersions caused by the third analog sub-string (304), and a third digital-to-analog converter (308); and the third analog subchain (304) including a third frequency upshift transposition circuit (312), a third upstream amplifier stage (314) disposed upstream of the third transposition circuit (312), a third downstream stage power amplifier (316) disposed downstream of the third transposition circuit (312).
[13" id="c-fr-0013]
13. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 12, wherein, the compensation device (234) of the frequency and time response of the first radio frequency channel (206) to be calibrated, comprises a digital compensation filter (266) and an adaptive or bulk optimizer (268) of the coefficients of the digital compensation filter, the compensation filter (266) being arranged directly upstream of the first radio frequency channel (206) to be calibrated, and directly downstream of the digital summator (244), and the adaptive optimizer (268) is configured to determine commands of the compensation filter coefficients (266) from measurements of a fourth observed signal taken directly downstream of the analog subtractor (238) and from the reference calibration signal from the reference generator (240).
[14" id="c-fr-0014]
14. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to claim 13, wherein the compensation device further comprises a fourth measurement chain (270) for carrying measurements of the fourth observed signal taken. directly downstream of the analog subtractor (238) to the adaptive optimizer (268), the fourth measurement chain (270) including a fourth frequency downconverting circuit (286), a fourth upstream amplifying stage (288) disposed upstream of the fourth downconverter circuit (286), a fourth downstream amplification stage (290) arranged downstream of the fourth transposition circuit (286).
[15" id="c-fr-0015]
15. A system for dynamically calibrating a radio frequency circuit of a satellite payload according to any one of claims 1 to 14, further comprising a second generator of one or more sampling clock signals, derived from a common reference clock signal provided by a second reference clock; and wherein when the first radio frequency channel to be calibrated comprises an ADC analog-to-digital converter and / or a DAC digital-to-analog converter, and / or when the second injection channel is analog and comprises a digital-to-analog converter DAC; and / or when the third supply chain of the adapted replica is analogue and comprises a DAC digital-to-analog converter; and / or when the fourth measurement chain is analog and includes an ADC analog-to-digital converter; and / or the digital-to-analog converter (s), and / or the digital-to-analog converter (s) are synchronized with one another through the local clock or local oscillator, shared and considered As the master, all analog-to-digital ADC and digital-to-analog converters DAC are configured to use the one or more sampling clock signals derived from the common reference clock signal provided by the second reference clock.
[16" id="c-fr-0016]
16. A method of dynamically calibrating a radio frequency circuit of a satellite payload, the radiofrequency circuit (4; 204) comprising a first radio frequency chain (6; 206) to be calibrated for amplification and filtering with or without transposition to a predetermined transposition frequency of a first input signal formed by the time sum of a second calibration signal and a third input useful signal, the first radio frequency channel (6; 206) to be calibrated on a band with a chain being between upstream a first upstream port (8; 208) receiving the first input signal and downstream a first downstream port (10: 210) providing a first output signal, the first signal output signal being the frequency and time response of the first radio frequency channel (6; 206) to be calibrated at the first input signal; the dynamic calibration method comprising the steps of: in a first step (564), an injection device injects a second calibration signal whose waveform is predetermined upstream of the first radiofrequency (6; 206) to be calibrated, the second calibration signal being directly injected in digital form or indirectly in analog form through a second analog injection chain from a reference calibration signal; then in a second step (566), a compensation device compensates, on the useful band of frequencies of the first channel to be calibrated, amplitude and phase disparities caused by the first string to be calibrated, using a compensation filter, arranged upstream or downstream of the first radio frequency channel to be calibrated, the compensation being made from measurements of a fourth signal, observed downstream of the first radio frequency channel to be calibrated and the compensation filter, or directly downstream of the first channel to be calibrated; and the dynamic calibration method being characterized in that it comprises a third step (568), performed after the first step, during which a temporal erasure device temporally erases the calibration signal injected with the aid of an analog (238) or digital (38; 138) subtractor connected downstream of the first channel to be calibrated.
[17" id="c-fr-0017]
A method of dynamically calibrating a radio frequency circuit of a satellite payload according to claim 16, wherein, the third step (568) is performed after the second step (566), the subtractor (238) is a subtractor analog, connected directly downstream of the first channel (206) to be calibrated, and the compensation filter (266) is a digital compensation filter arranged upstream of the radio frequency chain (206) to be calibrated, when the first channel (206) is the chain of an issuer; or the third step (568) is performed after the second step (566), the subtractor (38) is a digital subtractor connected directly downstream of the compensation filter (66), and the compensation filter (66) is a filter digital compensation device arranged directly downstream of the first chain (6) to be calibrated, when the first chain (6) to be calibrated is the chain of a receiver; or the third step (568) is performed before the second step (566), the subtractor (138) is a digital subtracter connected directly upstream the first string (6) to be calibrated and downstream the compensation filter (166), and the compensation filter (166) is a digital compensation filter, arranged directly downstream of the digital subtracter (138), when the first channel (6) to be calibrated is the receiver chain.

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同族专利:

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公开号 | 公开日

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EP3229383B1|2021-02-24|

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US10382192B2|2019-08-13|

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ES2860976T3|2021-10-05|

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CA2961384A1|2017-10-04|

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US20170288853A1|2017-10-05|

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EP3229383A1|2017-10-11|

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FR3049794B1|2019-04-12|

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法律状态:
2017-03-27| PLFP| Fee payment|Year of fee payment: 2 |

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2017-10-06| PLSC| Search report ready|Effective date: 20171006 |

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2018-03-27| PLFP| Fee payment|Year of fee payment: 3 |

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2020-03-26| PLFP| Fee payment|Year of fee payment: 5 |

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2021-03-25| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1600565|2016-04-04|

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FR1600565A|FR3049794B1|2016-04-04|2016-04-04|SYSTEM AND METHOD FOR DYNAMICALLY CALIBRATING ONE OR MORE RADIOFREQUENCY CHANNELS FOR TRANSMITTING A SATELLITE PAYLOAD|FR1600565A| FR3049794B1|2016-04-04|2016-04-04|SYSTEM AND METHOD FOR DYNAMICALLY CALIBRATING ONE OR MORE RADIOFREQUENCY CHANNELS FOR TRANSMITTING A SATELLITE PAYLOAD|

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US15/447,022| US10382192B2|2016-04-04|2017-03-01|System and method for dynamically calibrating one or more radiofrequency channels of a satellite payload|

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ES17158840T| ES2860976T3|2016-04-04|2017-03-02|System and procedure for dynamic calibration of one or more radio frequency chains of transmission of a satellite payload|

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EP17158840.3A| EP3229383B1|2016-04-04|2017-03-02|A dynamic calibration system and method within a satellite payload.|

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CA2961384A| CA2961384A1|2016-04-04|2017-03-20|System and method for dynamically calibrating one or more radiofrequency channels of a satellite payload|