FR2904899A1 - Variable rejection filter adjusting method for e.g. multistandard mobile terminal, involves performing voltage scanning operation based on control of variable elements of filter for shifting frequency band rejected from filter - Google Patents

Abstract

The method involves detecting over a received digital signal, the presence of a Global system for mobile communication (GSM) interference signal non-filtered in an output of a rejection filter (5) using a bandwidth peak detector (7), by comparing an output signal of the detector with a given GSM threshold using a comparator (8). A voltage scanning operation is performed based on control of variable elements of the filter for shifting a frequency band rejected from the filter. The detecting and scanning operations are iterated till the signal rejection is detected. An independent claim is also included for a device for controlling a variable rejection filter, comprising a detector.

Description

The invention relates to a method of adjusting a rejection filter

  variable, to a control device of the variable rejector filter and to a signal receiving device comprising such a device. It is part of the implementation of multistandard mobile terminals due to the integration of multiple functions such as, for example, the telephone, the game console, the digital agenda (PDA), the digital camera, the internet browser, email (email) in the same terminal. The implementation of multistandard terminals brings together applications such as the GSM-standard multi-band mobile phone (900, 1800 and 1900MHz), WLAN wireless LAN access at 2.4 and 5 GHz frequencies, and DVB digital television reception. -H for mobile terminals or DVB-T for fixed applications located in the UHF band (470-860 MHz).

  Figure 1 shows the DVB-T (H) frequency chart GSM 900MHz. It is worth noting the frequent proximity of GSM 900MHz standards and the UHF band for Europe. Since the DVB-H (T) mode is essentially a reception mode, it remains entirely permeable to the high level interference presented by the GSM 900 transmission channel located between 890 and 915 MHz. Leakage of 900MHz GSM transmit amplified signals to the other RF parts of the terminal can cause a noticeable deterioration of performance especially on the receiving parts. Cell phones with the GSM standard are capable of delivering a power of 33dBm or 2W. Nevertheless, the statistical studies show that the average transmission power is rather 20dBm, also in a close environment (about 1 m), a digital receiver is potentially in the presence of an interference on the order of -10dBm therefore at a high level compared to the sensitivity of the receiver located near -80dBm.

It is therefore imperative to insert a rejection filter of the GSM band directly after the antenna to avoid saturation of the low noise amplifier leading to a serious degradation of performance.

Currently, the notch filter rejection devices are not sufficiently selective to allow effective immunity of GSM emissions on the upper part of the UHF band. Indeed, the very small gap between the top of the UHF band and the 900MHz emission GSM spectrum clearly requires an ultra-selective filtering device. Simulations based on a Chebyshev synthesis with zero transmission shows that an 11-pole filter would allow noticeable attenuation of the GSM band but by amputating the UHF spectrum of the channels corresponding to reception frequencies higher than 820 MHz. Such a filter would therefore not allow total compliance of the equipment with the DVB-T standard. A conventional type of filtering with discrete elements does not ensure both the desired rejection of GSM and compliance with the DVB-T standard. A receiving device having a variable rejector filter is known from EP 0 812 069. This device makes it possible to suppress an interfering signal occurring in a mobile station of a dual-band cellular telephone system. Figure 2 shows such a device. A signal receiver 102 receives the signals received by an antenna 101 before sending them to a demodulator 103. A disturbing signal detecting circuit 106 transmits a control signal for frequency control of a variable frequency rejection filter 105. The circuits 103 and 104 allow to determine an insufficient signal to noise ratio. It therefore seems conceivable to make a notch filter satisfying the required criteria on this context, ie a rejection of about 20 dB of the GSM transmit band (890 MHz-915 MHz) based on a 2-pole topology. An example of such a filter is shown in Figure 3a. This filter comprises series-connected L and L / 4 inductors as well as coaxial resonators R formed by coaxial lines in series with capacitors C and interposed between the different inductances and the mass. Coaxial resonators are square section coaxial transmission lines with open-circuit or short-circuit reflective termination. These components based on a metallized ceramic bar with a high permittivity (from 10 to 90 depending on the material) make it possible to obtain quality coefficients of the order of 100 to 1000 depending on the profile chosen.

Although such an adaptive rejection circuit theoretically would allow, in our multi-band terminals, to remain compliant with the DVB-T standard and thus to allow reception of the channels at reception frequencies of up to 862 MHz, an analysis of However, the sensitivity of the adaptive rejector filter with a high quality coefficient and based on a 2-pole structure with coaxial resonators nevertheless shows that a tolerance of + 1- 1.6% on the dielectric constant and +/- 2% on the length of this component led out this filter of the desired template and thus makes this concept unusable in the context of a manufacturing of such a concept in large volume.

Figure 3b shows this sensitivity of the response to manufacturing tolerances. The transmission curve 2 corresponds to the ideal rejection filter. The frequency band thus rejected includes the GSM transmission frequency of 890-915 MHz. The extreme frequency of 862MHz, corresponding to the reception of DVB-T / H signals, is not rejected.

However, in view of the tolerances, the filter can, in the worst case, reject useful channels (> = 65) at the limiting frequencies of 860 MHz. Curve 1 represents the response curve of such a filter. In another case represented by the response curve 3, in view of the tolerance values, the band of frequency rejected by the filter is shifted to higher frequencies and there is no rejection of the GSM band but a rejection of the order of 20 dB of the frequency band above the GSM band. The current state of the art does not therefore allow, by a conventional type of filtering with discrete elements, to ensure both the desired rejection of the GSM and the compliance with the DVB-T standard.

In order to remedy these drawbacks, the concept proposed by the invention therefore consists in refocusing the filter on its gauge as soon as a high level GSM disturbance occurs.

The invention consists of a method of adjusting a variable element rejection filter of a given frequency band comprising the frequency of a disturbance signal occurring in a signal receiving system. Said method comprises the step of detecting on the received signal the presence of the unfiltered disturbance signal at the output of the filter, by comparing the output signal with a given threshold, and then following the presence of the disturbance signal, of performing a voltage scanning procedure on the control of the variable elements of the rejection filter thus allowing the shift of the frequency band rejected from the filter and then iterating the preceding steps of detection and scanning until the detection of the rejection of the signal of disturbance.

Preferably, the method of adjusting a rejection filter further comprises the step of determining the frequency proximity of the received signal and the disturbance signal, then measuring the signal-to-noise ratio C / N of the received signal and detecting the poor quality. the reception by comparing the signal-to-noise ratio at a determined threshold and then then performing a voltage scanning procedure on the variable elements of the rejection filter. The previous steps of measurement and scanning are iterated until a reception of good quality is detected.

According to a variant of the invention, the step of detecting the unfiltered disturbance signal comprises the following steps of measuring the signal received at the output of the filter, and then detecting by means of a broadband peak detector a voltage proportional to the received signal and then comparing this voltage to a determined threshold to emit a binary signal indicative of the presence of the disturbance signal. In one embodiment, the scanning procedure comprises the steps of determining, with the aid of a control block, a mean initial voltage control value of the variable elements of the filter, this value being situated between a minimum voltage Vmin and a maximum voltage Vmax determining the useful maximum frequency deviation of the rejection filter corresponding to the tolerance variations of the elements forming the filter and then incrementing the initial value of a value corresponding to a resolution step of the scanning voltage 5 AVr corresponding to a frequency variation Af of the rejected frequency band. The disturbance signal is for example a GSM interference in the frequency band 890 to 915 MHz, the received signal corresponds to the DVB-H / T standard.

The invention also consists in a device for controlling a variable element rejection filter of a frequency band tunable to the frequency of a disturbance signal comprising means for detecting the presence of the disturbance signal on the signal. received, and frequency adjusting means of the filter variable elements to adapt the rejected frequency band to the disturbance signal to be eliminated. Preferably, this device for controlling a rejection filter comprises a broadband peak detection device associated with a comparator for comparing the detected signal with a given threshold value. According to one variant of the invention, the means for adjusting the frequency of the variable elements of the filter comprise a control block for producing a control signal as a function of information relating to the presence of the disturbance signal, information relating to the frequency proximity of the received signal, the disturbance signal, and signal reception quality information and a digital to analog converter for converting the control signal to an analog control signal for frequency adjustment of the filter. Preferably, the variable elements of the filter are voltage-controllable varactors. According to one variant of the invention, the digital signals received correspond to the DVB-T or DVB-H standards and the disturbing signals correspond to the GSM 900 MHz standard.

The invention also consists in a device for receiving digital signals capable of interfering with other disturbing signals comprising a rejection filter of a frequency band tunable to the frequency of the disturbance signal. The new concept proposed here has the following features: advantage of overcoming the malfunctions caused by high level interference for terrestrial digital receivers placed in a near 900MHz cellular environment or in the context of multimedia terminals combining the digital terrestrial reception and GSM 900MHz cellular telephone functions. It will also open the complete UHF (Ultra High Frequency) band to the DVB-HIT mobile standard currently limited by the frequency proximity of the UHF band and the GSM 900 emission band. By conventional discrete element filtering it is not possible to provide both the desired GSM rejection and compliance with the DVB-T standard. This device makes it possible to detect the presence of potential GSM interferers and comes automatically refocus the filter on the GSM transmit band. The features and advantages of the invention mentioned above, as well as others, will appear more clearly on reading the following description, made with reference to the accompanying drawings, in which: FIG. 1 already described, represents the DVB-T / H frequency card 25 - GSM; FIG. 2 represents a diagram of the device according to the state of the art; FIG. 3a represents a topology of a 2-pole rejector filter; FIG. 3b shows the response curves of such a filter taking into account the sensitivity of the filter; FIG. 4a shows a topology of a frequency controllable 2-pole rejector filter; FIG. 4b represents a topology of a device according to the invention; FIGS. 5a, 5b and 5c show diagrams indicative of the relationship between the evolution of the voltage of the varactor and the frequency band rejected by the adaptive jet rejector; FIG. 6 represents an algorithm for centering the filter according to the invention. To simplify the description, the same references will be used in these last figures to designate elements fulfilling identical functions.

FIG. 1 shows the DVB-T / H frequency chart GSM, FIG. 2 showing a diagram of the device according to the state of the art as well as FIGS. 3a and 3b showing a topology of a 2-pole rejection filter having been briefly described above they will not be rewritten later. Moreover, the same reference is used for the circuit of the state of the art and for the circuits according to the invention when it concerns the same element.

The proposed concept whose topology is illustrated in Figure 4b. It consists of a receiving antenna 1 for receiving the DVB-T / H signals. These signals may contain interfering due to the near transmission of GSM signals. The signal reception chain associated with the antenna is conventionally formed by an LNA amplifier 2, a Tuner element 3 and a demodulator 4. The signal received by the antenna is thus amplified, selected and demodulated. A rejection filter 5 for rejecting the interfering frequencies GSM is interposed between the antenna and the amplifier. This filter is, for example, a coaxial resonator 2-pole filter as described in FIG. 3a and in which the addition of variable elements such as a varactor V and a capacitor C in parallel on each of the resonators allows a frequency adjustment by a signal Vvar. This filter is represented by FIG. 4a.

An adjustment circuit 6 delivers a frequency control signal Vvar of the varactor. This circuit is formed by a broad band peak detector 7, a comparator 8, a digital control block 9 and a digital analog converter CNA 10.

The wideband peak detector 7 delivers a voltage proportional to the signal present at the output of the low noise amplifier 2. The comparator 8 is responsible for producing a GSM-int disturbance presence information as soon as the output signal of the detector 7 is above a pre-programmed GSM Threshold threshold, indicating the presence of a GSM interferer. A value of the threshold order of 40dBm would, for example, seem realistic in this context. The digital control block 9 has input parameters for developing a significant digital signal of the voltage control to be applied to the adaptive filter. These input parameters are the GSM-int signal described above, an Info-channel information signal, the number of the channel selected by the tuner's synthesizer and the value of the C / N noise carrier ratio which is a criterion of calculated quality within the demodulator. A relatively simple algorithm is based on these 3 parameters. And the block thus delivers a digital signal in relation to these parameters. The digital-to-analog converter translates the digital information given by an 8-bit word, for example, from the control block 6 into an analog voltage signal Vvar for controlling the varactors of the filter and thereby varying the rejection frequency of the rejection filter. FIGS. 5a, 5b and 5c show diagrams indicative of the relationship between the evolution of the voltage of the varactor and the frequency band rejected by the adaptive jet rejector. The voltage applied to the varactor of the filter 5 is such that for a value of average voltage Vmoy the bandwidth 890-915MHz of central frequency 897 MHz is rejected. The calculation of the tolerances of the elements of the filter makes it possible to determine the bandwidth rejected with a minimum tolerance (you min) and the bandwidth rejected with a maximum tolerance (you max). Figure 3b illustrates a minimum bandwidth at 20dB of 855 at 880MHz and a maximum bandwidth at 20dB from 920 to 945MHz. The frequency deviation Af of the varactor is determined by the difference between the center frequencies of the minimum and maximum pass bands, which corresponds to a variation of the control voltage from a value V min to a value V max. If the filter is not stalled on the GSM transmit band because of the tolerances on the coaxial resonators, it can not exert its filter function of the desired frequency band. If the filter is shifted to its minimum value, as shown in FIG. 5b, the value of the voltage V applied to the varactor being Vmoy, it is necessary to increase this value towards Vmax. The filter is thus recentered and the desired frequency band is filtered.

If the filter is shifted to its maximum value, as shown in FIG. 5c, the value of the voltage V applied to the varactor being Vmoy, it is necessary to decrease this value towards Vmin. The filter is thus recentered and the desired frequency band is filtered. The scanning pitch is determined by the minimum voltage difference of the varactor obtained by incrementing a unit of the CNA element 10. FIG. 6 represents an algorithm for centering the filter according to the invention. This algorithm is triggered by step 100 with detection of the receive signal followed by step 102 with channel selection. If during step 104 an interference is detected either GSM-int = 1, it means that the filter is not wedged on the GSM transmit band because of the tolerances on the coaxial resonators mentioned above; the next step 106 is then started, which is a scanning procedure which consists in performing a voltage sweep on the varactors of the filter, thus making it possible to deviate the maximum drift of the resonators. It is possible to initialize the control value V applied to the varactor, that is to say its mean value Vmoy and to scan upwards and downwards values 30 or vice versa, either on its minimum value Vmin or maximum Vmax and on the other hand. scan accordingly to rising or falling values.

The steps of detecting the interference (step 104) and scanning (step 106) in voltage are then iterated until the filter passes through its optimal position, the GSM-int information then switches to its GSM-int value = 0 indicating that the disturbance signal has been filtered. During the next step (step 108) it will be tested if the channel selected by the tuner is less than 65, a frequency lower than 826MHz to determine if the selected channel has a frequency remote from the frequency of the interferers.

As the selected channel is less than 65, it is assumed that the signal is sufficiently far away from potential disturbing signals and thus free from these GSM interference signals. After verifying that the scanning is activated (step 110), the latter is stopped (step 112) on the last recorded control voltage value. If there is no GSM disturbance, that is to say that the scanning procedure has not been activated, the information transmitted to the DAC converter is fixed (XXX) (step 114), which means that whatever the position of the GSM filter, there is no implication on the reception.

As the selected channel is greater than 65, a frequency higher than 826MHz, even if the signal is cleared of GSM interferers, signal reception is poor. This may mean that the frequency drift of the filter is such that it rejects the channel to be received, a probable case for channels 66 to 69 if the filter is in a low tolerance, the signal-to-noise ratio test C / N with respect to a preprogrammed threshold (step 114) is then positive and a scanning procedure is started again (step 106). This is iterated and stops as previously by steps 112 or 114 only when the filter passes through the optimal centering.

Other algorithms based on the same selection criteria are conceivable.

In particular, it would be possible to reverse the steps of testing the channel number (step 108) and interference detection (step 104). Other variants are similarly conceivable.

An algorithm based on a solution which would consist in imposing on the filter to set itself at the high limit when the terminal is turned on, the upper limit corresponding to a zero voltage on the varactors is conceivable. The scanning procedure would therefore control only a decrease in frequency of the filter until the passage below the threshold of the detected disturbance. This mode of operation would thus prevent the filter from amputating the upper channels (65 to 69) and guarantee operation in the complete band even in the absence of a GSM disturbance; this then leads to a simplified algorithm of the concept where the dependent steps of the higher channels are suppressed.

It is important to note that all the functions necessary for this adaptive loop, apart from the filter, can be inserted into the digital demodulator circuit and thus do not require component modifications on the existing receivers. 20 25

Claims (3)

  1. A method of adjusting a variable element rejector filter of a given frequency band comprising the frequency of a disturbance signal occurring in a signal receiving system, said method is characterized in that it comprises the steps following: -detect on the received signal, the presence of the unfiltered disturbance signal at the output of the filter, by comparing the output signal with a given threshold (step 104); following the presence of the disturbance signal, performing a voltage sweeping procedure on the control of the variable elements of the rejection filter thus enabling the offset frequency band of the filter to be shifted (step 106); and - iterating the preceding steps of detection and scanning until the detection of the rejection of the disturbance signal.   2. A method of adjusting a rejection filter according to claim 1 characterized in that it further comprises the steps of: -determining the frequency proximity of the received signal and the disturbance signal (step 108); measuring the signal-to-noise ratio C / N of the received signal and detecting the poor quality of the reception by comparing the signal-to-noise ratio at a determined threshold (step 116); then performing a voltage scanning procedure on the variable elements of the rejection filter (step 106); - iterate the previous measurement and scanning steps until a good quality reception is detected.   3. A method of adjusting a rejection filter according to claim 1 characterized in that the step of detecting the unfiltered disturbance signal (step 104) comprises the following steps of: measuring the signal received at the output of the filter; - detect with a broadband peak detector a voltage proportional to the received signal; comparing this voltage with a determined threshold (GSM threshold) to emit a binary signal indicative of the presence of the disturbance signal. A method of adjusting a rejection filter according to claim 1, characterized in that the step of performing the scanning procedure comprises the following steps: determining, by means of a control block, an initial value Average voltage command Vmoy of the variable elements of the filter, this value being situated between a minimum voltage Vmin and a maximum voltage Vmax determining the useful maximum frequency deviation of the rejection filter corresponding to the tolerance variations of the elements forming the filter; incrementing the initial value of a value corresponding to a resolution step of the voltage sweep AVr corresponding to a variation of frequency Af of the rejected frequency band. A method of adjusting a rejection filter according to claim 1, characterized in that the disturbance signal is a GSM interference in the frequency band 890 to 915 MHz, the received signal corresponds to the DVB-H / T standard. 6 Control device (6) for a variable element rejection filter (5) of a frequency band tunable to the frequency of a disturbance signal, characterized in that it comprises: - detection means (7) , 8) the presence of the disturbance signal on the received signal; frequency adjusting means (9, 10) of the variable elements of the filter for adapting the rejected frequency band to the disturbance signal to be eliminated. 7 Control device of a rejection filter according to claim 6 characterized in that the detection means (7, 8) comprise a broadband peak detection device (7) associated with a comparator for comparing the detected signal with a given threshold value. 8 Control device of a rejection filter according to claim 5 7, characterized in that: - the frequency adjusting means (9, 10) of the variable elements of the filter comprise a control block (9) for producing a control signal based on information (GSM-int) relating to the presence of the perturbation signal, information relating to the frequency proximity of the received signal (channel info), the disturbance signal and information relating to the signal reception quality (C / N); and - a digital to analog converter (10) for converting the control signal into an analog control signal (Vvar) for frequency adjustment of the filter. 15 9 Control device of a rejection filter according to claim 8 characterized in that the variable elements of the filter comprise varactors controllable voltage. A device for controlling a rejection filter according to claims 6 to 9, characterized in that the received digital signals correspond to the DVB-T or DVB-H standard. 11 Control device of a rejection filter according to claims 6 to 9, characterized in that the disturbing signals correspond to the GSM 900 MHz standard. 12 Device for receiving digital signals capable of interfering with other disturbance signals, characterized in that it comprises a rejector filter (5) of a frequency band corresponding to a disturbance signal, adjustable by the control device. control according to claims 6 to 11.