FR2752503A1 - SECAM television receiver decoder filter - Google Patents

Abstract

The filter has a switchable bandpass filter stage (BPF) which is sampled at six times the filter centre frequency to produce a filtered frequency. The filtered frequency is fed to two mixers (M1,M2) which convert the frequency output to 1.5*(filter centre frequency). The output is sampled to produce half the band pass centre frequency. The output is then limited (ACCF) and demodulated to provide the chrominance (FMDEMOD) signal (B-Y,R-Y).

Description

The present invention relates to a SECAM decoding filter, a SECAM decoding method and a device comprising such a SECAM decoding filter, and a SECAM television receiver comprising such a decoding device.
SECAM.

 US-A-4,929,300 describes a method and a device for adjusting a resonant circuit coupled to a frequency discriminator. The resonant circuit is, for example, the "bell" circuit of a SECAM decoding unit. The known bell filter is an analog circuit comprising a resistor, a coil, and capacitors.

The bell filter may include capacitors switched by integrated switches which make given capacitors of the circuit inactive or active, thus allowing adjustment of the total capacitor. The result of a measurement operation is applied to an element which acts on the adjustment of the resonant circuit.

The object of the invention is in particular to provide a precise SECAM decoding filter whose central frequency has a fixed ratio to the clock frequency and which, therefore, does not require adjustment. To this end, a first aspect of the invention provides a SECAM decoding filter as defined by claim 1. A second aspect of the invention provides a SECAM decoding device according to claim 2. A third aspect of the invention provides a decoding process
SECAM according to claim 4. A fourth aspect of the invention provides a SECAM television receiver according to claim 5. An advantageous embodiment is defined by dependent claim 3.

 According to one aspect of the invention, a SECAM decoder filter (or bell filter) is a switched capacity filter which operates at a fixed sampling frequency of 6 * pin. This means that the central frequency of the filter has a fixed relation to regard to the clock frequency. Although the switched capacity filter according to the invention is more complex than the filter of the prior art, it offers the advantage of a precise fully integrated filter, which therefore no longer requires tedious adjustments.

In a SECAM decoder in accordance with another aspect of the invention, SECAM signals are filtered at a fixed sampling frequency of six times the bell-shaped bell frequency in order to deliver bell-filtered signals, the bell-filtered signals are mixed at a frequency 1.5 times the bell frequency F bell to transpose the filtered bell signals to a frequency of 0.5 times the bell frequency
Spindle to provide mapped SECAM signals, mapped SECAM signals are limited to provide limited SECAM signals, and signals
SECAM limited are demodulated to deliver chroma signals. Thus, the bell filter was placed before a discrete time decoder. The input signal is mixed at 1v5 * FCloche) so that the filtered SECAM signal is transposed to 0.5 * FCloche. In this way, no distortion produced returns to the signal band.

 These and other aspects of the invention will emerge from the embodiments described below and will be explained with reference to the latter.

In the drawings
Fig. 1 shows an embodiment of a SECAM television receiver comprising a first embodiment of a SECAM decoding device according to the invention;
Fig. 1A shows a plurality of frequency spectra further illustrating the operation of the embodiment of FIG. 1;
Fig. 2 shows a second embodiment of a decoding device
SECAM according to the invention, and
Fig. 3 shows an embodiment of a SECAM decoding filter according to the invention.

Fig. 1 shows an embodiment of a SECAM television receiver comprising a SECAM decoding device for sampled signals comprising a bell filter with switched capacities at 6 * Foch according to the invention. A CVBS SECAM input signal is applied to an ACCS slow saturation automatic control circuit via a CPF continuous time pre-filter. On the
Fig. 1A, curve (a) illustrates the frequency spectrum of the input signal with distortions, and curve (b) illustrates the transfer characteristic of the low-pass CPF pre-filter. An output signal from the ACCS circuit is applied to a BPF switched capacity bell bandpass filter to which a 6 * Foche switching signal is applied. In Fig. 1A, curve (c) illustrates the transfer characteristic of the BPF discrete time bell filter, and curve (d) illustrates the frequency spectrum of the output signal of the BPF bell filter. An output signal from the BPF filter is applied to a first mixer M1 which multiplies by a sine function given by the coefficients 1 1 -1 -1, and to a second mixer M2 which multiplies by a cosine function given by the coefficients 1 -1 -1 1. The input signal is mixed 1.5 times Filoche (see the arrows in (e) in Fig. 1A), so that the signal
SECAM filtered is transposed to 0.5 times Floche In Fig. 1A, the frequency spectrum of the transposed SECAM signal is illustrated in (f). The outputs of mixers M1 and M2 are applied to the respective inputs of a fast ACC circuit ACCf via respective low-pass filters LPF1 and LPF2, to which a switching signal with 6 * pin is applied. In FIG. 1A, the curve (g) illustrates the transfer curve of the low-pass filters LPF1 and LPF2 with a suppression at 2.5 times Floches and the curve (h) illustrates the frequency spectrum of the output signals of the low-pass filters
LPF1 and LPF2.

The ACC ACC fast circuit is used to replace the limiter which is present in a SECAM decoder in standard continuous time. This replacement is based on the recognition that, in an embodiment in discrete time, a simple clipping action would cause significant phase errors. However, even a very good ACC circuit produces some distortion and it is for this reason that the input signal is not transposed into baseband, so that no distortion produced is folded back into the signal band but that these distortions are displaced around O Hz and Floche. This is why mixing of the input signal takes place at 1.5 * pin 'so that the filtered SECAM signal is transposed to 0.5 * F
The low-pass filters LPF1, LPF2 are used to eliminate the higher order harmonics of the SECAM signal transposed to 0.5 * pin. Now that we have decided to mix the input signal at 1.5 * pin) the BPF bell filter before the mixers M1, M2 must be clocked at a frequency which is equal to an even number of times the bell frequency in order to provide for delays of whole clock periods, and which must also be a multiple of the mixing frequency of 1.5 * bell in order to provide for an embodiment of the mixers with a few (for example 2) simple coefficients (for example - 1 and +1) only. From these considerations, it appears that the filter bell
BPF must operate at 6 * floche
In the ACCF circuit, the signal from the low-pass filter LPF1 is applied to a variable gain amplifier A1, the output signal of which constitutes an output signal from the ACCF circuit. The output signal from amplifier A1 is also applied to a quadrature circuit Q1. In addition, the signal from the low-pass filter LPF2 is applied to an amplifier A2 with variable gain, the output signal of which constitutes another output signal from the circuit ACCF. The output signal from amplifier A2 is also applied to a quadrature circuit Q2. An adder AD supplies the sum of the output signals of the quadrature circuits Q1 and Q2 to an inverting input of a comparator C1, whose non-inverting input receives a reference voltage Vref. An output of comparator C1 is applied to the control inputs of the variable gain amplifiers A1, A2, and to a slow loop filter
LF. An output of the loop filter LF is applied to an inverting input of a comparator C2, whose non-inverting input receives a reference voltage Vref. An output of the comparator oe is applied to a control input of the slow ACC circuit
ACCS. It should be noted that an amplitude control showing certain similarities with the ACCF fast ACC circuit has been illustrated in FIG. 5 of the document
DE-A-31 19 448. In FIG. 1A, the curve (i) illustrates the frequency spectrum of the output signal of the fast ACC circuit ACCF with a distortion by second harmonic 2nd Har Dist and a distortion by third harmonic 3rd Har Dist.

The output signals of the variable gain amplifiers A1, A2 of the fast ACC circuit ACCF are applied to the respective inputs of an FM demodulator, FMD, which supplies chrominance signals BY and RY. In Fig. 1A, curve (j) illustrates the conversion from FM to AM. These chrominance signals BY and RY are, with a luminance signal Y derived from the input signal CVBS, applied to a matrix circuit
MX to produce color signals B (blue), R (red) and G (green). The color signals B, R and G are applied to a display unit D via respective output amplifiers OA1, OA2 and OA3.

Fig. 2 shows an embodiment of a SECAM decoding device in continuous time comprising a bell filter with switched capacities at 6 * F bell in accordance with the invention. The CVBS SECAM input signal is applied to a SECAM decoder in SD continuous time via a CPF continuous time pre-filter, an ACCS slow ACC circuit, a BPF switched capacity bell bandpass filter operating at 6 * pin, and a CF continuous-time post-filter. SECAM decoder
SD delivers BY and RY chrominance signals which can then be processed as shown in Fig. 1. In this embodiment, the use of a bell filter with switched capacities operating at 6 * F bell offers the advantage that it places less stringent requirements on the CPF pre-filter and on the CF post-filter.

Fig. 3 shows a recursive embodiment of a decoding filter
SECAM according to the invention. The decoding filter is a bell filter with quasi-differential switched capacities with load redistribution. According to one aspect of the invention, the sampling frequency 1 / T is equal to 6 * floche In the embodiment of FIG. 3, each set of switched capacities comprises 4 capacities, the switches of which are actuated according to 4 mutually different switching phases in each set. Consequently, an output of an OTA differential amplifier is applied to capacities C1, C12, C13 and C14 via first switches Sl.l1, Sl.12, Sl.13 and 81.14, respectively. An input signal Vin is applied to capacitors C1, C12, C13 and C14 via second switches S2.11, S2.12, S2.13 and S2.14, respectively. Third switches S3.11, S3.12,
S3.13 and S3.14 connect capacitors C11, C12, C13 and C14, respectively, to the inverting input (-) of the differential amplifier OTA. Fourth switches S4.11, S4.12, S4.13 and S4.14 ground the capacitors Cli, C12, C13 and C14, respectively, to ground.

The filter also includes four other capacitors C21, C22, C23 and C24 having first switches Sl.21, Sl.22, Sl.23 and S1.24, respectively, and second switches S2.21, S2.22, S2. 23 and S2.24, respectively, which ground the left side of the additional capacitors C21, C22, C23 and C24. Third switches S3.21, S3.22, S3.23 and S3.24, respectively, ground the right side of capacitors C21, C22, C23 and C24, respectively. Fourth switches S4.21, S4.22, S4.23 and S4.24 connect the right side of the capacitors
C21, C22, C23 and C24, respectively, at the non-inverting (+) input of the OTA differential amplifier.

In addition to this, the recursive filter includes a similar number of reaction chains. More specifically, in addition to each direct switched capacity circuit (capacity + corresponding switches) between the Vin input of the filter and the inverting input (-) of the OTA differential amplifier, a switched reaction capacity circuit is present between the output and the respective input of the OTA differential amplifier. The switches in these switched reaction capacitor circuits are actuated at the same switching phases as the corresponding switches of the direct switched capacitor circuits. Consequently, on the
Fig. 3, the same references have been used for the direct switched capacitor assemblies and the switched reaction capacitor assemblies, the reaction elements being therefore indicated by an additional "f". The second capacity switches between the output and the inverting input of the OTA differential amplifier are grounded instead of being connected to the Vin input. The first capacitor switches connected to the non-inverting input of the OTA differential amplifier are connected to the output of the OTA differential amplifier instead of being grounded.

 In the embodiment of FIG. 3, the value of each of the reaction capacities is worth nine times the capacity of each of the direct capacities.

 It should be noted that the embodiments mentioned above illustrate the invention but do not limit it, and that the experts in the technique will be able to design many variant embodiments without departing from the scope of the invention. . Instead of the embodiment of FIG. 3 of the present application, the embodiment of FIG. 5 of patent application EP no. 95202849.6 filed on 20.10.95, with its corresponding applications incorporated by reference, if its sampling frequency 1 / T is equal to 6 * bell in accordance with an embodiment of the invention . While a frequency of 6 * Bell is mentioned in this description, the multiples of the latter also fall within the scope of the invention. Frequencies substantially equal to the frequencies mentioned in this description also fall within the scope of this invention.

Claims (5)

CLAIMS: 1. SECAM decoding filter, characterized in that it comprises a switched capacity bell filter (BPF) for filtering SECAM signals at a fixed sampling frequency of six times the bell (bell) frequency in order to deliver filtered signals Bell. 2. SECAM decoding device, characterized in that it comprises  a switched capacity bell filter (BPF) to filter signals SECAM at a fixed sampling frequency of six times the bell (bell) frequency in order to deliver filtered bell signals;  means (M1, M2) for mixing said bell filtered signals at a frequency of 1.5 times the bell frequency (floche) for transposing said bell filtered signals at a frequency of 0.5 times the bell frequency (bell) so to provide transposed SECAM signals;  means (ACCF) for limiting said transposed SECAM signals in order to provide limited SECAM signals, and  means (FMD) for demodulating said limited SECAM signals in order to deliver chrominance signals (B-Y, R-Y). 3. SECAM decoding device according to claim 2, characterized in that it further comprises low-pass filtering means (LPF1, LPF2) between the said mixing means (M1, M2) and the said limiting means (ACCF) to suppress the harmonics of said transposed SECAM signals. 4. SECAM decoding method, characterized in that it comprises the following steps:  filter (BPF) SECAM signals at a fixed sampling frequency of six times the bell (bell) frequency to deliver filtered bell signals;  mix (M1, M2) the said filtered bell signals at a frequency of 1.5 times the bell frequency (F bell)> to transpose the said filtered bell signals at a frequency of 0.5 times the bell frequency (bell) in order to deliver the signals SECAM transposed;  limit (ACCF) the said SECAM signals transposed in order to provide limited SECAM signals, and  demodulating (FMD) said limited SECAM signals in order to deliver chrominance signals (B-Y, R-Y). 5. SECAM television receiver, characterized in that it comprises  a SECAM decoding device according to claim 2 for supplying chrominance signals (B-Y, R-Y);  means (MX) for matrixing said chrominance signals (B-Y, R Y) and a luminance signal (Y) to obtain color signals (B, R, G); and  means (D) for displaying said color signals (B, R, G).