JP2011193360A - Reception device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reception device that reduces a wide-band unwanted wave. <P>SOLUTION: The reception device 10 includes a notch filter 8 and a filter controller 14. The filter controller 14 estimates a center frequency f<SB>0</SB>and a stop band width W<SB>0</SB>of the unwanted wave based upon a signal of a frequency region from an FFT 13, and outputs the estimated center frequency f<SB>0</SB>and stop band width W<SB>0</SB>to the notch filter 8. The notch filter 8 reduces a frequency band determined by the center frequency f<SB>0</SB>and stop band width W<SB>0</SB>received from the filter controller 14, i.e. the band of the unwanted wave from a base band signal. Consequently, when the band of the unwanted wave becomes wide, the estimated stop band width W<SB>0</SB>increases. Then the notch filter 8 reduces the band of the unwanted waves from the base band signal using the stop band width W<SB>0</SB>which has been increased. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a receiving apparatus, and more particularly to a receiving apparatus that reduces unnecessary waves.

  Recently, spread spectrum modulation signals, frequency-scheduled OFDM (Orthogonal Frequency-Division Multiplexing) modulation signals, and frequency-scheduled single-carrier modulation (SC-FDMA: Single-Carrier Frequency Multiple Access, etc.) Communication using a wideband modulated signal of several tens of MHz or more has been put into practical use (Non-Patent Document 1).

  Such a wideband modulated signal is usually converted into digital data over the entire band by an AD converter, and unnecessary waves are removed or suppressed by a digital filter formed as a bandpass filter or a matched filter, and demodulated. The

  However, if a strong unnecessary wave exists in the band subjected to AD conversion, the reception sensitivity is lowered for the following reason.

  When the AD converter is saturated by a strong input, the digital filter and the demodulation process do not operate correctly. Therefore, an operation of lowering the gain is usually performed by an AGC (Auto Gain Control) circuit or an attenuator provided in the receiver.

  As a result, since the level of the desired wave input to the AD converter is reduced, the number of effective quantization bits for the desired wave is reduced, the signal-to-noise ratio is lowered, and sensitivity suppression occurs.

  For example, a 12-bit AD converter has a dynamic range of about 60 to 65 dB, but the dynamic range by modulation of the desired wave itself needs to be at least 10 dB or more. If it is stronger than 50 dB, reception is impossible.

  As a method for solving this problem, a technique for removing or reducing unnecessary waves using a notch filter capable of changing the center frequency has been proposed (Patent Document 1). As a result, it is possible to remove or reduce a narrow band of unnecessary waves and to prevent an excessive decrease in the gain of the AGC circuit.

JP 2005-80272 A

Takeshi Hattori, Masanobu Fujioka, “Wireless Broadband HSPA + / LTE / SAE Textbook,” Impress R & D, 2009, ISBN: 978-4844327387.

  However, the conventional receiving apparatus has a problem that it cannot cope with a wideband unnecessary wave because the stop band of the variable notch filter is fixed.

  Accordingly, the present invention has been made to solve such a problem, and an object of the present invention is to provide a receiving apparatus capable of reducing broadband unnecessary waves.

  According to this invention, the receiving apparatus includes a notch filter, an AD converter, a frequency analysis unit, and a filter control unit. The notch filter reduces unwanted waves from the received signal by using an attenuation characteristic including a center frequency and an attenuation bandwidth. The AD converter converts the output signal of the notch filter from an analog signal to a digital signal. The frequency analysis means performs frequency analysis on the received signal digitized by the AD converter by digital calculation. The filter control means estimates the center frequency and occupied bandwidth of the unwanted wave based on the analysis result of the frequency analysis means, and sets the center frequency and attenuation bandwidth of the notch filter to the estimated center frequency and occupied bandwidth, respectively. To control the notch filter.

  Preferably, the filter control means determines the attenuation amount of the notch filter from the estimated value of the occupied bandwidth of the unnecessary wave so that the attenuation amount of the unnecessary wave by the notch filter is maximized.

  Preferably, the notch filter has a plurality of center frequencies. The filter control means determines the attenuation bandwidth of the notch filter for each center frequency of the notch filter from the number of unnecessary waves and the estimated value of the occupied bandwidth.

  Preferably, the notch filter includes a plurality of single attenuation pole notch filters, a plurality of bypass circuits, and a plurality of switch circuits. Each of the plurality of single attenuation pole notch filters has one center frequency and is continuously connected. The plurality of bypass circuits are provided corresponding to the plurality of single attenuation pole notch filters, and each directly connects the input and output of the single attenuation pole notch filter without going through the single attenuation pole notch filter. The plurality of switch circuits are provided corresponding to the plurality of single attenuation pole notch filters, and each is connected to the input side and the output side of one single attenuation pole notch filter. Then, the filter control means further controls the plurality of switch circuits so as to connect the switch circuit to the corresponding single attenuation pole notch filter or bypass circuit according to the number and intensity of unnecessary waves.

  In the receiving apparatus according to the embodiment of the present invention, the filter control means estimates the center frequency and stop bandwidth of the unwanted wave based on the analysis result of the frequency analysis means, and calculates the estimated center frequency and stop bandwidth. Output to the notch filter, and the notch filter reduces the frequency band determined by the center frequency and the stop bandwidth received from the filter control means, that is, the band of the unwanted wave from the baseband signal. As a result, if the unnecessary wave band becomes wide, the estimated stop bandwidth becomes wide. The notch filter reduces the band of unnecessary waves from the baseband signal by using the widened stop bandwidth.

  Therefore, even if the band of the unnecessary wave becomes wide, it is possible to reduce the wideband unnecessary wave.

It is a block diagram of the receiver by embodiment of this invention. 3 is a flowchart for explaining a reception operation of the reception apparatus illustrated in FIG. 1. It is a block diagram of the other receiver by embodiment of this invention. It is a block diagram of the notch filter shown in FIG. It is a 1st conceptual diagram which shows the characteristic of a notch filter. It is a 2nd conceptual diagram which shows the characteristic of a notch filter. 4 is a flowchart for explaining a reception operation of the reception device shown in FIG. 3.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

  FIG. 1 is a configuration diagram of a receiving apparatus according to an embodiment of the present invention. Referring to FIG. 1, a receiving device 10 according to an embodiment of the present invention includes an antenna 1, a BPF (Band Pass Filter) 2, an LNA (Low Noise Amplifier) 3, a multiplier 4, a local oscillator 5, Baseband LPF (Low Pass Filter) 6, AGC 7, notch filter 8, baseband amplifier 9, AD converter 11, signal intensity detector 12, FFT (Fast Fourier Transform) 13, filter control Means 14 and demodulation means 15 are provided.

  The antenna 1 receives a radio wave and outputs the received radio wave to the BPF 2. The BPF 2 is a high-frequency BPF, and allows a received radio wave in a desired frequency band among the received radio waves to pass to the LNA 3. In this case, the desired frequency band has a frequency range in which the spectrum of the received radio wave can exist, and is normally set to match the frequency band for which operation is permitted or a partial band thereof.

  The LNA 3 amplifies the received radio wave received from the BPF 2 and outputs the amplified received radio wave to the multiplier 4.

The multiplier 4 multiplies the received radio wave from the LNA 3 by the local oscillation signal (frequency = f _L ) from the local oscillator 5 to convert the frequency of the received radio wave.

Local oscillator 5 oscillates a local oscillation signal having a frequency f _L and outputs the oscillated local oscillation signal to multiplier 4.

  The baseband LPF 6 is equivalent to that used in a general direct conversion receiver, and blocks frequency components other than the desired baseband signal in the received radio wave from the multiplier 4. The passband width of the baseband LPF 6 is between the upper end and the lower end of the desired signal spectrum in the baseband signal, and the cut-off frequency of the baseband LPF 6 is a sufficient passband that can include the desired signal spectrum. To be determined.

  The AGC 7 receives a desired baseband signal from the baseband LPF 6 and receives a signal strength from the signal strength detector 12. Then, the AGC 7 is based on the signal strength, the average value of the signal voltage detected from the digital signal converted by the AD converter 11 is within a predetermined range, the input of the AD converter 11 is not saturated, and The baseband signal is amplified so that the dynamic range of the input signal can be secured as much as possible.

The notch filter 8 receives the center frequency f ₀ of the unwanted wave and the stop bandwidth W ₀ from the filter control means 14. The notch filter 8 reduces the frequency band determined by the center frequency f ₀ and the stop bandwidth W ₀ from the baseband signal.

  The baseband amplifier 9 amplifies the baseband signal that has passed through the notch filter 8 to a level sufficient for converting the analog signal into a digital signal by the AD converter 11.

  The AD converter 11 converts the baseband signal amplified by the baseband amplifier 9 from an analog signal to a digital signal, and outputs the converted digital signal to the signal intensity detector 12, the FFT 13, and the demodulation unit 15.

  The signal strength detector 12 detects the signal strength of the digital signal received from the AD converter 11 and outputs the detected signal strength to the AGC 7.

  The FFT 13 performs fast Fourier transform on the digital signal received from the AD converter 11 and outputs a frequency domain signal to the filter control means 14.

  The FFT 13 is used for spectrum analysis means, and may be configured to form a plurality of band pass filters by digital signal processing and output the output level.

Filter control means 14, based on the signal in the frequency domain from the FFT 13, to estimate the center frequency f ₀ and stop bandwidth W ₀ of the unnecessary wave, the notch filter center frequency f ₀ and stop bandwidth W ₀ and the estimated Output to 8.

  The demodulator 15 demodulates the digital signal from the AD converter 11 and outputs a received signal.

  The notch filter 8 is composed of a resonance circuit or a combination of LPF and HPF (High Pass Filter).

When the notch filter 8 is formed of a resonance circuit, the stop bandwidth W ₀ of the notch filter 8 is controlled by the resonance Q value. In this case, the filter control means 14 controls the stop bandwidth W ₀ of the notch filter 8 using the Q value by the following method.

  If the spectrum of the unwanted wave is S (ω) (ω is the angular frequency of the signal) and the transfer function of the notch filter 8 is H (ω, Q), the filter control means 14 uses U = | H (ω, Q ) Determine the Q value so that S (ω) |

  And the filter control means 14 updates Q value using the steepest gradient method, for example. Moreover, the filter control means 14 calculates several U using several Q value, and selects Q value when U becomes the minimum.

  Since the transfer function H (ω, Q) is known and S (ω) is estimated by the FFT 13, the partial differentiation of U with respect to Q depends on the rate of change ΔU / ΔQ of U with respect to a minute change ΔQ of Q. Calculated.

  Therefore, an algorithm for recursively updating the Q value by the steepest gradient method is expressed by the following equation.

  Q (updated value) = Q−μΔU / ΔQ (1)

  In Expression (1), μ is a step size. For example, if the step size μ is defined as U = 10 log | H (ω, Q) S (ω) |, it is in the range of 1 to 10.

  Accordingly, when using the steepest gradient method, the filter control unit 14 updates the Q value using the equation (1), and outputs the updated Q value to the notch filter 8.

  On the other hand, when the filter control means 14 selects the Q value when U becomes the smallest by several Q values, the filter control means 14 sets the value corresponding to the attenuation bandwidth equal to the maximum bandwidth considered as an unnecessary wave to the minimum Q The maximum value of Q is set to the minimum bandwidth or the minimum bandwidth of the desired signal.

  FIG. 2 is a flowchart for explaining the receiving operation of the receiving apparatus 10 shown in FIG. Referring to FIG. 2, when the reception operation is started, antenna 1 receives a radio wave (step S1) and outputs the received radio wave to BPF 2.

  Then, the BPF 2 passes the received radio wave in a desired frequency band among the received radio waves to the LNA 3. Thereafter, the LNA 3 amplifies the received radio wave received from the BPF 2 and outputs the amplified received radio wave to the multiplier 4.

Subsequently, the multiplier 4 multiplies the received radio wave from the LNA 3 by the local oscillation signal (frequency = f _L ) from the local oscillator 5, and converts the received radio wave into a baseband signal (step S2). Then, the baseband LPF 6 blocks a frequency component other than the desired baseband signal from the received radio wave from the multiplier 4 and passes the desired baseband signal to the AGC 7. In the AGC 7, based on the signal strength from the signal strength detector 12, the average value of the signal voltage detected from the digital signal converted by the AD converter 11 falls within a predetermined range, and the input of the AD converter 11 is saturated. In addition, the baseband signal is amplified so as to secure the dynamic range of the input signal as much as possible.

The filter control means 14 estimates the center frequency f ₀ and the stop bandwidth W ₀ of the unnecessary wave based on the frequency domain signal from the FFT 13 (step S3), and the estimated center frequency f ₀ and the stop bandwidth W ₀ is output to the notch filter 8. The notch filter 8 reduces the frequency band of the unnecessary wave determined by the center frequency f ₀ and the stop bandwidth W _{0 of} the unnecessary wave received from the filter control unit 14 from the baseband signal (step S4).

  Thereafter, the baseband amplifier 9 amplifies the baseband signal that has passed through the notch filter 8 to a level sufficient for converting the analog signal into a digital signal by the AD converter 11. The AD converter 11 converts the baseband signal amplified by the baseband amplifier 9 from an analog signal to a digital signal, and outputs the converted digital signal to the signal strength detector 12, the FFT 13, and the demodulation unit 15.

  Thereafter, the signal strength detector 12 detects the signal strength of the digital signal received from the AD converter 11 and outputs the detected signal strength to the AGC 7. The FFT 13 performs a fast Fourier transform on the digital signal received from the AD converter 11 and outputs a frequency domain signal to the filter control means 14.

  On the other hand, the demodulator 15 demodulates the digital signal from the AD converter 11 and outputs a received signal (step S5). This completes the reception operation.

As described above, in the receiving apparatus 10, the filter control unit 14 estimates the center frequency f ₀ and the stop bandwidth W ₀ of the unnecessary wave based on the frequency domain signal from the FFT 13, and the estimated center frequency f ₀ and the stop bandwidth W ₀ are output to the notch filter 8, and the notch filter 8 is a frequency band determined by the center frequency f ₀ and the stop bandwidth W ₀ received from the filter control means 14, that is, a band of unnecessary waves. Is reduced from the baseband signal. As a result, if the unnecessary wave band becomes wide, the estimated stop bandwidth W ₀ becomes wide. The notch filter 8 is reduced from the baseband signal bandwidth of the unnecessary wave by using the stop band width W ₀ it became the widely.

  Therefore, even if the band of the unnecessary wave becomes wide, it is possible to reduce the wideband unnecessary wave.

  FIG. 3 is a configuration diagram of another receiving apparatus according to the embodiment of the present invention. The receiving apparatus according to the embodiment of the present invention may be receiving apparatus 10A shown in FIG. Referring to FIG. 3, receiving apparatus 10A is obtained by replacing notch filter 8 of notifying filter 8A of receiving apparatus 10 shown in FIG. 1 with notch filter 8A, and filter control means 14 with filter control means 14A. Same as device 10.

  The notch filter 8A has a plurality of stop bands and reduces one or more unnecessary wave bands from the baseband signal.

  The filter control means 14A controls the notch filter 8A so as to reduce one or more unnecessary wave bands from the baseband signal.

  FIG. 4 is a configuration diagram of the notch filter 8A shown in FIG. Referring to FIG. 4, notch filter 8 </ b> A includes switches SW <b> 1 to SW <b> 4, notch filters 81 and 83, and detour circuits 82 and 84.

  Switch SW1, notch filter 81, switch SW2, switch SW3, notch filter 83, and switch SW4 are connected in series. The bypass circuit 82 is provided corresponding to the notch filter 81, and is arranged in parallel with the notch filter 81 between the switch SW1 and the switch SW2. The bypass circuit 84 is provided corresponding to the notch filter 83, and is arranged in parallel with the notch filter 83 between the switches SW3 and SW4.

  The switch SW1 is connected to the terminal TM1 or the terminal TM2 by a signal SG1 from the filter control means 14A. In this case, the switch SW1 is connected to the terminal TM1 when the signal SG1 is “1”, and is connected to the terminal TM2 when the signal SG1 is “0”.

  The terminal TM1 is connected to the input side of the notch filter 81. The terminal TM2 is connected to the input side of the bypass circuit 82. The terminal TM3 is connected to the output side of the notch filter 81. The terminal TM4 is connected to the output side of the bypass circuit 82.

Notch filter 81 receives center frequency f ₁ and stop bandwidth W ₁ from filter control means 14A, and reduces the band of unwanted waves determined by the received center frequency f ₁ and stop bandwidth W ₁ from the baseband signal. To do. The notch filter 81 outputs a baseband signal with a reduced unnecessary wave band to the terminal TM3.

  The bypass circuit 82 passes the baseband signal from the terminal TM2 to the terminal TM4. The switch SW2 is disposed between the terminals TM3 and TM4 and the switch SW3. The switch SW2 is connected to the terminal TM3 or the terminal TM4 by a signal SG2 from the filter control means 14A. In this case, the switch SW2 is connected to the terminal TM3 when the signal SG2 is “1”, and is connected to the terminal TM4 when the signal SG2 is “0”.

  The switch SW3 is connected to the terminal TM5 or the terminal TM6 by a signal SG3 from the filter control means 14A. In this case, the switch SW3 is connected to the terminal TM5 when the signal SG3 is “1”, and is connected to the terminal TM6 when the signal SG3 is “0”.

  The terminal TM5 is connected to the input side of the notch filter 82. The terminal TM6 is connected to the input side of the bypass circuit 84. The terminal TM7 is connected to the output side of the notch filter 83. The terminal TM8 is connected to the output side of the bypass circuit 84.

Notch filter 83 receives the center frequency f ₂ and stop bandwidth W ₂ from the filter control means 14A, reducing the bandwidth of the undesired wave is determined by the center frequency f ₂ and stop bandwidth W ₂ thereof received from the baseband signal To do. The notch filter 83 outputs a baseband signal with a reduced unnecessary wave band to the terminal TM7.

  The bypass circuit 84 passes the baseband signal from the terminal TM6 to the terminal TM8. The switch SW4 is connected to the terminal TM7 or the terminal TM8 by a signal SG4 from the filter control means 14A. In this case, the switch SW4 is connected to the terminal TM7 when the signal SG4 is “1”, and is connected to the terminal TM8 when the signal SG4 is “0”.

The filter control means 14A detects the number N of unnecessary waves (N = 0, 1, 2, 3,...) Based on the frequency domain signal from the FFT 13, and the detected N unnecessary waves. The center frequency f _i and the stop bandwidth W _i (1 ≦ i ≦ N (≠ 0)) are detected. In the following, the maximum number of N is, for example, 2.

Then, the filter control means 14A detects one unnecessary wave, and when the center frequency and the stop bandwidth of the detected one unnecessary wave are the center frequency f ₁ and the stop bandwidth W ₁ , respectively, the center frequency f ₁ and stop band width W ₁ are output to notch filter 81, signals SG1 and SG2 consisting of 1 are output to switches SW1 and SW2, respectively, and signals SG3 and SG4 consisting of 0 are output to switches SW3 and SW4, respectively.

Accordingly, the switch SW1 is connected to the terminal TM1, the switch SW2 is connected to the terminal TM3, the switch SW3 is connected to the terminal TM6, and the switch SW4 is connected to the terminal TM8. As a result, notch filter 81 reduces the band of unnecessary waves (band determined by center frequency f ₁ and stop bandwidth W ₁ ) from the baseband signal input via terminal TM ₁ and outputs the reduced band to terminal TM 3. . The bypass circuit 84 passes the baseband signal output from the notch filter 81 from the terminal TM6 to the terminal TM8.

Further, when the filter control unit 14A detects a single unnecessary wave, the center frequency and the stop bandwidth of one undesired wave detection is the center frequency f ₂ and stop bandwidth W _2, respectively, the center frequency the f ₂ and stop bandwidth _{W 2} and outputs to the notch filter 83, and output signals consisting of 0 SG1, SG2 to the respective switches SW1, SW2, and outputs the signal SG3, SG4 comprising one to each switch SW3, SW4.

Accordingly, the switch SW1 is connected to the terminal TM2, the switch SW2 is connected to the terminal TM4, the switch SW3 is connected to the terminal TM5, and the switch SW4 is connected to the terminal TM7. As a result, the bypass circuit 82 passes the baseband signal received through the terminal TM2 from the terminal TM2 to the terminal TM4. Notch filter 83 reduces the band of unnecessary waves (band determined by center frequency f ₂ and stop bandwidth W ₂ ) from the baseband signal input through terminal TM 5 and outputs the reduced signal to terminal TM 7.

Further, the filter control means 14A detects two unnecessary waves, and the detected center frequencies and stop bandwidths of the two unnecessary waves are the center frequencies f ₁ and f ₂ and the stop bandwidths W ₁ and W _{2, respectively.} , The center frequency f ₁ and the stop bandwidth W ₁ are output to the notch filter 81, the center frequency f ₂ and the stop bandwidth W ₂ are output to the notch filter 83, and the signals SG1 to SG4 consisting of 1 are respectively switched. Output to SW1 to SW4.

Accordingly, the switch SW1 is connected to the terminal TM1, the switch SW2 is connected to the terminal TM3, the switch SW3 is connected to the terminal TM5, and the switch SW4 is connected to the terminal TM7. As a result, notch filter 81 reduces the band of unnecessary waves (band determined by center frequency f ₁ and stop bandwidth W ₁ ) from the baseband signal input via terminal TM ₁ and outputs the reduced band to terminal TM 3. . Notch filter 83 reduces the band of unnecessary waves (band determined by center frequency f ₂ and stop bandwidth W ₂ ) from the baseband signal input through terminal TM 5 and outputs the reduced signal to terminal TM 7.

  Further, the filter control means 14A outputs signals SG1 to SG4 consisting of 0 to the switches SW1 to SW4, respectively, when no unnecessary wave is detected.

  Accordingly, the switch SW1 is connected to the terminal TM2, the switch SW2 is connected to the terminal TM4, the switch SW3 is connected to the terminal TM6, and the switch SW4 is connected to the terminal TM8.

  As a result, the bypass circuit 82 passes the baseband signal received through the terminal TM2 from the terminal TM2 to the terminal TM4. Then, the bypass circuit 84 passes the baseband signal received via the terminal TM6 from the terminal TM6 to the terminal TM8.

  As described above, the notch filter 8A reduces the unnecessary wave band from the baseband signal according to the number N of unnecessary waves and the band of unnecessary waves in accordance with the control from the filter control unit 14A, and no unnecessary waves are detected. The baseband signal is passed from the input side to the output side.

  Therefore, when unnecessary waves are not detected, or when the number N of unnecessary waves is smaller than the number of notch filters 81 and 83, the insertion loss of the filter is eliminated by bypassing the notch filter 81 and / or the notch filter 83. Can improve sensitivity.

  5 and 6 are first and second conceptual diagrams showing the characteristics of the notch filter 8A, respectively.

  When the number of unnecessary waves is one (= the number N of unnecessary waves is smaller than the number of notch filters), the filter control unit 14A preferably controls the notch filter 8A as follows.

That is, when there is one unnecessary wave, the filter control unit 14A controls the center frequencies f ₁ and f ₂ so that the stop bands of the two notch filters 81 and 82 overlap each other. Referring to FIG. 5, curve k 1 is the frequency characteristic of notch filter 81, and curve k 2 is the frequency characteristic of notch filter 83. In this case, the filter control unit 14A controls the center frequencies f ₁ and f ₂ so that the frequency characteristics k1 and k2 overlap each other. As a result, the notch filter 8A has a frequency characteristic indicated by the curve k3.

  Therefore, greater attenuation of unwanted waves can be obtained.

Further, when there is one unnecessary wave, the filter control unit 14A controls the center frequencies f ₁ and f ₂ so that the stop bands of the two notch filters 81 and 82 are adjacent to each other. Referring to FIG. 6, curve k4 is the frequency characteristic of notch filter 81, and curve k5 is the frequency characteristic of notch filter 83. In this case, the filter control unit 14A controls the center frequencies f ₁ and f ₂ so that the frequency characteristics k4 and k5 are adjacent to each other. As a result, the notch filter 8A has a frequency characteristic indicated by the curve k6.

  Therefore, it is possible to obtain the attenuation of unnecessary waves in a wider band.

  The filter control unit 14A performs the same functions as the filter control unit 14 in other respects.

  FIG. 7 is a flowchart for explaining a receiving operation of the receiving apparatus shown in FIG. Referring to FIG. 7, when the reception operation is started, the same operations as steps S1 and S2 shown in FIG. 2 are executed (steps S11 and S12).

  Then, the filter control unit 14A detects the number of unnecessary waves based on the frequency domain signal from the FFT 13 (step S13), and determines whether or not the number N of unnecessary waves is “0” (step S13). S14).

When it is determined in step S14 that the number N of unnecessary waves is not “0”, the filter control unit 14A estimates the center frequency f _i and the stop bandwidth W _i of the unnecessary waves (step S15).

The notch filter 8A reduces the band of unnecessary waves from the baseband signal according to the number N of unnecessary waves, the center frequency f _{i of} unnecessary waves, and the stop bandwidth W _i by the above-described method (step S16). ).

  Thereafter, the baseband signal is converted from an analog signal to a digital signal and demodulated (step S17).

  On the other hand, when it is determined in step S14 that the number of unnecessary waves is “0”, the notch filter 8A bypasses the notch filters 81 and 82 and passes the baseband signal (step S18). And a series of operation | movement transfers to step S17.

  When the series of operations proceeds from step S16 to step S17, conversion and demodulation of the baseband signal with reduced unnecessary waves into a digital signal are performed in step S17. Further, when the series of operations proceeds from step S18 to step S17, conversion and demodulation of a baseband signal without unnecessary waves into a digital signal are performed in step S17.

  And a series of operation | movement is complete | finished after step S17.

  In the above description, the AGC 7 has been described as being arranged downstream of the baseband LPF 6. However, the present invention is not limited to this, and the AGC 7 has a wide input dynamic range and low distortion. In some cases, the AGC 7 may be arranged in front of the baseband LPF 6.

  In this case, an increase in noise figure due to the insertion loss of the baseband LPF 6 is suppressed, and the sensitivity can be improved.

  In the above description, the notch filters 8 and 8A have been described as being inserted into the baseband band (the processing region after being converted into the baseband signal). However, in the embodiment of the present invention, the present invention is not limited thereto. Instead, in the superheterodyne method, notch filters 8 and 8A may be inserted in the intermediate frequency circuit.

  Further, in the above description, the notch filter 8A includes the two notch filters 81 and 82. However, the embodiment of the present invention is not limited to this, and the notch filter 8A includes three or more notches. A filter may be included, and generally two or more notch filters may be included.

  Furthermore, in the embodiment of the present invention, the FFT 13 constitutes a “frequency analysis means”, the notch filters 81 and 82 each constitute a “single attenuation pole notch filter”, and the notch filters 81 and 82 “Multiple single attenuation pole notch filters” are configured.

  Furthermore, in the embodiment of the present invention, the bypass circuits 82 and 84 constitute “a plurality of bypass circuits”, and the switches SW1 to SW4 constitute “a plurality of switch circuits”. In this case, the switches SW 1 and SW 2 constitute a “switch circuit” provided corresponding to the notch filter 81, and the switches SW 3 and SW 4 constitute a “switch circuit” provided corresponding to the notch filter 83. .

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

  The present invention is applied to a receiving apparatus that reduces unnecessary waves.

  1 antenna, 2 BPF, 3 LNA, 4 multiplier, 5 local oscillator, 6 baseband LPF, 7 AGC, 8, 8A, 81, 82 notch filter, 9 baseband amplifier, 10, 10A receiver, 11 AD converter , 12 Signal strength detector, 13 FFT 14, 14A Filter control means, 15 Demodulation means.

Claims (4)

A notch filter that reduces unwanted waves from the received signal using an attenuation characteristic consisting of a center frequency and an attenuation bandwidth;
An AD converter for converting the output signal of the notch filter from an analog signal to a digital signal;
Frequency analysis means for performing frequency analysis on the received signal digitized by the AD converter by digital calculation;
Based on the analysis result of the frequency analysis means, the center frequency and the occupied bandwidth of the unnecessary wave are estimated, and the center frequency and the attenuation bandwidth of the notch filter are set to the estimated center frequency and the occupied bandwidth, respectively. And a filter control means for controlling the notch filter.   2. The reception according to claim 1, wherein the filter control unit determines an attenuation amount of the notch filter from an estimated value of an occupied bandwidth of the unnecessary wave so that an attenuation amount of the unnecessary wave by the notch filter is maximized. apparatus. The notch filter has a plurality of center frequencies;
The filter control means determines the attenuation bandwidth of the notch filter for each center frequency of the notch filter from the number of unnecessary waves and the estimated value of the occupied bandwidth. Receiver device. The notch filter is
A plurality of single-attenuating pole notch filters each having a center frequency and continuously connected;
A plurality of bypass circuits that are provided corresponding to the plurality of single attenuation pole notch filters, each directly connecting the input and output of the single attenuation pole notch filter without going through the single attenuation pole notch filter;
A plurality of switch circuits provided corresponding to the plurality of single attenuation pole notch filters, each connected to an input side and an output side of one single attenuation pole notch filter;
The filter control means further controls the plurality of switch circuits to connect the switch circuit to the corresponding single attenuation pole notch filter or the bypass circuit according to the number and intensity of the unnecessary waves. The receiving device according to any one of claims 1 to 3.

Images