JP3731276B2 - Receiving machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a receiver configured to amplify a baseband signal generated from a received signal by a variable gain amplifier, and to eliminate the influence of a DC offset voltage component specific to a receiving circuit included in the baseband signal.
[0002]
[Prior art]
Today, receivers in wireless communication systems are becoming smaller and lighter. As a small and lightweight receiver, there is a receiver called a direct conversion receiver. A direct conversion receiver directly converts an RF (Radio Frequency) signal received via an antenna into a baseband signal without converting it into an IF (Intermediate Frequency) signal. Therefore, there is an advantage that the required parts can be reduced and the receiver can be reduced in size and weight.
[0003]
FIG. 10 shows “direct conversion receiver using baseband AGC”, Miyuki Soetani, Takashi Ueno, Hiroshi Tsurumi, IEICE Spring Conference B-322, 1993. 1 is a configuration diagram of a conventional direct conversion receiver described in 1).
[0004]
In FIG. 10, 1 is an antenna, 2 is an amplifier, 3 is a band-pass filter, 4a and 4b are mixers, and the output signal of the band-pass filter 3 is branched into two and is connected to one input terminal of each of the mixers 4a and 4b. It is designed to be entered.
[0005]
6a and 6b are low-pass filters, 8a and 8b are variable gain amplifiers, and the output signals of the low-pass filters 6a and 6b are inputted to one input terminals of the variable gain amplifiers 8a and 8b, respectively.
[0006]
Further, 10a and 10b are A / D converters, 12 is a data decision unit, 13 is a phase shifter that shifts the phase of the input signal by π / 2, 14 is a carrier oscillator, and an output signal of the carrier oscillator 14 (Carrier signal) is branched into two and is input to one input terminal of the mixer 4 a and the phase shifter 13. The output signal of the phase shifter 13 (the signal shifted by π / 2) is input to one input terminal of the mixer 4b.
[0007]
Reference numeral 15 denotes a gain control voltage generator for controlling the variable gain amplifiers 8a and 8b. The gain control voltage generator 15 is supplied with output signals of the A / D converters 10a and 10b and gain control voltage. Output signals (control voltages) from the generator 15 are input to the input terminals of the variable gain amplifiers 8a and 8b, respectively.
[0008]
Next, the operation of the conventional direct conversion receiver configured as described above will be described with reference to FIG.
[0009]
An RF (R0adio Frequency) signal including a baseband signal received via the antenna 1 is amplified at a predetermined fixed amplification factor input to the amplifier 2. The output signal of the amplifier 2 is input to the band pass filter 3 to remove unnecessary frequency components.
[0010]
Further, the output signal of the band pass filter 3 is branched into two, and one of the signals is input to the mixer 4a and is multiplied by an output signal (carrier signal) as described later from the carrier oscillator 14 by the mixer 4a.
[0011]
Here, the carrier oscillator 14 outputs a carrier signal having the same frequency as the signal received via the antenna 1. Therefore, the output signal (multiplied signal) of the mixer 4a includes a baseband signal and a signal having a frequency twice the frequency of the carrier signal (carrier frequency).
[0012]
On the other hand, the other signal branched from the bandpass filter 3 is input to the mixer 4b and multiplied with the output signal of the phase shifter 13. As will be described later, the output signal of the mixer 4b is input to a low-pass filter 6b to extract a baseband signal.
[0013]
The low-pass filters 6a and 6b remove a frequency signal that is twice the unnecessary carrier frequency from the output signals of the mixers 4a and 4b, and output only baseband signals, respectively.
[0014]
The baseband signals output from the low-pass filters 6a and 6b are input to the variable gain amplifiers 8a and 8b, respectively, and are amplified to a predetermined appropriate amplitude for input to the A / D converters 10a and 10b, respectively. Is done.
[0015]
The output signals of the variable gain amplifiers 8a and 8b are converted into digital signals by the A / D converters 10a and 10b, respectively. The output signals of the A / D converters 10a and 10b are each branched into two, and one of the branched signals is input to the data determination unit 12.
[0016]
The data determiner 12 determines digital data to be output based on these two inputs, and the data determiner 12 outputs demodulated data as the determination result.
[0017]
The other signals that are output from the A / D converters 10a and 10b and further branched and not input to the data decision unit 12 are both input to the gain control voltage generator 15, and the gain control voltage generator 15 Based on these input signals, a control voltage serving as a control signal for controlling the gain of the variable gain amplifiers 8a and 8b is determined and output to the variable gain amplifiers 8a and 8b.
[0018]
The variable gain amplifiers 8 a and 8 b both change the gain (amplification factor) corresponding to the control signal (control voltage) of the gain control voltage generator 15.
[0019]
In this case, the gain control voltage generator 15 has a case where the input signal is less than a predetermined value based on the input signal that is a signal branched from the A / D converters 10a and 10b. Output a control signal (control voltage) that increases the gains of the variable gains 8a and 8b, and conversely, if this specified value is exceeded, the gains of the variable gain amplifiers 8a and 8b decrease. Outputs control voltage.
[0020]
In this way, the signal output from the variable gain amplifier 8a to the A / D converter 10a and from the variable gain amplifier 8b to the A / D converter 10b is always set to a constant amplitude.
[0021]
The conventional direct conversion receiver is configured in this way, and when the direct conversion receiver is used for mobile communication on land, the received signal power is greatly changed by the distance between the base station and the mobile. Since the received signal power also changes greatly due to fading, the gain amplification factors of the variable gain amplifiers 8a and 8b are set to make the input signal amplitudes of the A / D converters 10a and 10b constant. For example, the value needs to be as large as 80 (dB).
[0022]
However, in reality, a DC offset voltage component (hereinafter referred to as DC offset) specific to this circuit is generated inside the low-pass filters 6a and 6b and the variable gain amplifiers 8a and 8b, and the variable gain amplifiers 8a and 8b At the input point, there are a DC offset generated in the low-pass filters 6a and 6b and a DC offset generated in the variable gain amplifiers 8a and 8b.
[0023]
Generally, although the amount of these DC offsets is small, when the maximum gain of the variable gain amplifiers 8a and 8b for amplifying the baseband signal is large, these DC offsets are greatly amplified and output from the variable gain amplifiers 8a and 8b. The baseband signals respectively input to the A / D converters 10a and 10b include a greatly amplified DC offset.
[0024]
The amplified DC offset included in each of the input signals to the A / D converters 10a and 10b causes a data misjudgment at the time of data judgment in the subsequent data judgment unit 12, and has a bit error rate characteristic. There is a problem of deterioration.
[0025]
For example, even if the DC offset of the input terminals of the variable gain amplifiers 8a and 8b is only 100 (μV), the maximum gain is 80 (dB) (10 ^80/20 = 10 ^Four )In the case of,
100 μV × 10 ^Four = 1 (V) (1)
Therefore, at the time of the maximum gain, the baseband signal input to the A / D converters 10a and 10b is 1 (V) although it should be several mV if not originally affected by the DC offset. A very large DC offset is included.
[0026]
“Double-frequency digital phase-shifting demodulation direct conversion receiver”, Masahiro Mimura, Motoi Ohba, Makoto Hasegawa, Miomoto Maki, Koji Yokozaki, IEICE Spring Meeting B-211, 1991. FIG. 11 shows a conventional direct conversion receiver shown in FIG.
[0027]
In FIG. 11, 11a and 11b are high-pass filters as new configurations with respect to the conventional example described above, and the outputs of the variable gain amplifiers 8a and 8b are respectively input to the high-pass filters 11a and 11b. The output is input to the A / D converters 10a and 10b.
[0028]
In such a direct conversion receiver, a high-pass filter 11a inserted between the variable gain amplifier 8a and the A / D converter 10a, and a high-pass inserted between the variable gain amplifier 8b and the A / D converter 10b. The DC offset is removed by the filter 11b.
[0029]
However, the direct conversion receiver shown in FIG. 11 has a problem that a part of the spectrum of the baseband signal is deleted depending on the modulation method as described below.
[0030]
The direct conversion receiver shown in FIG. 11 has a configuration of a direct conversion receiver when a transmission signal is modulated by a modulation method called frequency shift keying (hereinafter referred to as FSK modulation).
[0031]
In the case of FSK modulation, the spectrum of the baseband signal output from the low-pass filters 6a and 6b exists only in the vicinity of a frequency of several kHz, for example, and does not exist in the vicinity of 0 Hz.
[0032]
Therefore, even if the DC offset (0 Hz signal) and the low frequency component of less than several kHz are simultaneously removed by the high-pass filters 11a and 11b set to a cutoff frequency of less than several kHz, the bit error rate characteristics are deteriorated. There is no problem.
[0033]
However, when the transmission signal is modulated by a modulation method called phase shift keying (hereinafter referred to as PSK modulation), which is mainly used in recent mobile communications, it is output from the low-pass filters 6a and 6b. The spectrum of the baseband signal is continuously present up to 0 Hz.
[0034]
Therefore, the high-pass filters 11a and 11b simultaneously remove not only the DC offset component but also the low-frequency component of the baseband signal, and the baseband signal is distorted to deteriorate the bit error rate characteristics.
[0035]
As described above, when the conventional direct conversion receiver is used in a communication system in which the received signal power greatly fluctuates, there is a problem that the bit error rate characteristic is deteriorated due to a greatly amplified DC offset.
[0036]
Further, in the conventional method of removing the DC offset component, the low frequency component is deleted, and therefore, when receiving a PSK modulated wave, a part of the spectrum of the baseband signal is also deleted. There was a point.
[0037]
[Problems to be solved by the invention]
The present invention has been made to solve such a problem, and in the circuit of a receiver included in a baseband signal that causes a data error determination when determining data of demodulated data to be output from the receiver. It is an object of the present invention to obtain a receiver capable of eliminating the generated offset voltage inherent in the circuit.
[0038]
[Means for Solving the Problems]
A receiver according to the present invention receives a phase shift modulated radio signal to generate a baseband signal and amplifies the baseband signal in accordance with the power of the radio signal. DC offset voltage output means for outputting a DC offset voltage specific to the circuit using means equivalent to at least the means for amplifying the baseband signal, and DC offset voltage component specific to the reception circuit generated from the received signal received by the receiving circuit DC offset voltage canceling means for canceling and outputting the DC offset voltage component output from the DC offset voltage output means from the baseband signal including the signal.
[0039]
The DC offset voltage output means includes a DC offset voltage control circuit that determines the magnitude of the DC offset voltage component specific to the receiving circuit based on the output of the DC offset voltage canceling means in the non-calling state. .
[0040]
The DC offset voltage output means is unique to the receiving circuit based on the average value of the output of the first DC offset voltage canceling means in the non-calling state and the output of the second DC offset voltage canceling means in the non-calling state. A DC offset voltage control circuit for determining the magnitude of the DC offset voltage component is included.
[0041]
The DC offset voltage control circuit includes an A / D converter for A / D converting the output result of the DC offset canceling means, a smoothing circuit for smoothing the output of the A / D converter, and an output of the smoothing circuit. DC offset voltage calculation circuit that calculates the magnitude of the DC offset voltage to a level that eliminates the influence of the DC offset voltage component unique to the receiver circuit from the voltage, and the DC offset voltage based on the through signal output from the timing control circuit A hold circuit that outputs the DC offset voltage calculated by the calculation circuit and holds and outputs the DC offset voltage calculated last by the DC offset voltage calculation circuit based on the hold signal output from the timing control circuit; A D / A converter that D / A converts the output.
[0042]
The DC offset voltage control circuit counts the number of positive / negative determination results output from the determination circuit and the determination circuit that determines whether the output result of the DC offset canceling means is positive or negative, and the positive or negative count value is A random fork filter that outputs the result of determination when it reaches a predetermined number and repeats counting again, and a large amount that cancels the DC offset voltage component specific to the receiver circuit based on the output of the random fork filter In addition, the voltage adjustment circuit that determines the magnitude of the DC offset voltage and the DC offset voltage determined by the voltage adjustment circuit based on the through signal output from the timing control circuit and the hold signal output from the timing control circuit Based on the hold circuit that holds and outputs the DC offset voltage that the voltage regulator circuit last determined based on the The output of the circuit is obtained is composed of a D / A converter for converting D / A.
[0043]
The timing control circuit outputs a through signal between immediately after turning on the power and a predetermined time.
[0044]
The timing control circuit outputs a hold signal during non-calling.
[0045]
Further, the DC offset voltage output means is a fixed voltage generation means for generating a voltage determined in advance that cancels out the DC offset voltage component unique to the receiving circuit.
[0046]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
FIG. 1 is a configuration diagram of a receiver (direct conversion receiver) according to the first embodiment.
In FIG. 1, 16a and 16b are subtractors, 18a and 18b are variable gain amplifiers, that is, the variable gain amplifiers 8a, 8b, 18a and 18b are all elements having similar characteristics. In any case, the gain is determined based on a certain input signal (applied voltage) for determining one gain.
[0047]
The subtractors 16a and 16b output signals obtained by subtracting the output signals (hereinafter referred to as replica DC offsets) of the variable gain amplifiers 18a and 18b from the output signals (amplified baseband signals) of the variable gain amplifiers 8a and 8b, respectively. It is supposed to be.
[0048]
Reference numerals 20a and 20b denote offset voltage control circuits. The offset voltage control circuits 20a and 20b both receive the output signals of the subtractors 16a and 16b, respectively, and amplify DC included in the output signals of the subtractors 16a and 16b. Voltage E that detects the offset and cancels these DC offsets to zero _a , E _b And the voltage E based on a timing signal which is an output signal of a timing control circuit described later. _a , E _b Is to hold each.
[0049]
Reference numeral 22 denotes a voltage generator. The voltage generator 22 generates a preset voltage for operating the variable gain amplifiers 8a, 8b, 18a, and 18b with the maximum gain.
[0050]
Reference numeral 23 denotes a selection switch, which is output by the timing control circuit 24. _i Level or L _o Based on the level timing signal, one of the output voltage (terminal A) as the output signal of the gain control voltage generator 15 and the output voltage (terminal B) as the output signal of the voltage generator 22 is changed to a variable gain. The amplifier 8a, 8b, 18a, 18b is selected as a voltage acquisition source for determining the gain (amplification factor).
[0051]
Then, the output voltage selected by the selection switch 23 is input to the variable gain amplifiers 8a, 8b, 18a, and 18b, respectively. The output baseband signal is amplified and output.
[0052]
Further, based on the terminal selected by the selection switch 23, the variable gain amplifiers 18a and 18b also have a gain based on the applied voltage, and the voltage E that is the output of the offset voltage control circuits 20a and 20b. _a , E _b Are amplified and output.
[0053]
The variable gain amplifiers 18a and 18b and the offset voltage control circuits 20a and 20b detect the amplified DC offset included in the output signals of the subtractors 16a and 16b, and a replica DC offset that cancels this DC offset to zero. The replica DC offset generation means 100 to generate is comprised.
[0054]
Further, the DC offset canceling means 101 is configured to perform a process of canceling these DC offsets to zero using the above-described replica DC offsets by the subtractors 16a and 16b.
[0055]
The timing control circuit 24 _i Level or L _o A level timing signal is output to control switching of the operation timing of these means.
[0056]
Next, the operation of the receiver according to the first embodiment configured as described above will be described with reference to FIGS.
[0057]
The receiver first operates the variable gain amplifiers 8a, 8b, 18a, and 18b at the maximum gain (that is, a fixed gain) in a non-reception state immediately after the power is turned on (immediately after starting the receiver). , A voltage for canceling out the DC offset inherent in the circuit and already occurring at the input points of the variable gain amplifiers 8a and 8b, for example, the voltage E, as described above. _a , E _b The operation for obtaining each is performed (step 1 in FIG. 2).
[0058]
Next, these voltages E _a , E _b In the gain control of these amplifiers performed by the gain control voltage generator 15 in the normal reception operation, the voltage E _a , E _b Based on the above, an operation for canceling out the DC offset specific to this circuit is performed (step 2 in FIG. 2).
[0059]
These two operations are switched based on a timing signal output from the timing control circuit 24.
[0060]
In FIG. 1, first, when the power is turned on and the receiver is activated, the timing control circuit 24 _i A level timing signal is output to the selection switch 23.
[0061]
The selection switch 23 outputs the output signal (H _i On the basis of the level timing signal), the control voltage capturing source for determining the gain of each of the variable gain amplifiers 8a, 8b, 18a, 18b is selected as the terminal B to which the voltage generator 22 is connected.
[0062]
Therefore, terminal B is selected and voltage E _a , E _b Is determined, the variable gain amplifiers 8a, 8b, 18a, and 18b are all operated at the maximum gain (ie, fixed gain).
[0063]
Here, for example, assuming that the maximum gains of these amplifiers are all 80 (dB) and the DC offsets inherent to the circuit already generated at the input points of the variable gain amplifiers 8a and 8b are 100 (μV), respectively. When all the amplifiers are operated at the maximum gain, the DC offset of 1 (V) is amplified and included in the output signals of the variable gain amplifiers 8a and 8b, respectively, according to the above equation (1).
[0064]
Since the variable gain amplifiers 18a and 18b are also operated at a maximum gain of 80 (dB), the variable gain amplifiers 8a, 8b, 18a and 18b are all operated at the maximum gain in the offset voltage control circuits 20a and 20b. In some cases, the respective replica DC offsets output from the variable gain amplifiers 18a, 18b are operated so as to cancel out the amplified DC offset inherent in the circuit contained in the output signals of the variable gain amplifiers 8a, 8b. Voltage E to be detected by detecting the amplified DC offset included in the output signals of the devices 16a and 16b. _a , E _b For each.
[0065]
And these voltages E _a , E _b Is held by the offset voltage control circuits 20a and 20b when the receiver enters a normal reception state by the output of the timing signal output from the timing control circuit 24.
[0066]
As described above, the voltage voltage E _a , E _b , The timing control circuit 24 _o A level timing signal is output, and the selector switch 23 is switched from the terminal B to the terminal A, so that the receiver is in a normal reception state.
[0067]
H _i L from the level timing signal _o Switching to a level timing signal is activated when the receiver is activated _i After the level timing signal is output, it is performed after a predetermined short time has elapsed.
Therefore, the voltage E described above _a , E _b Is calculated in a short time after activation of the receiver.
[0068]
When the receiver is started up, the voltage E described above every time the power is turned on. _a , E _b In such a short time, the output signal of the variable gain amplifiers 8a and 8b is included in the output signal of the variable gain amplifiers 8a and 8b even if the amount of DC offset inherent to the circuit due to temperature change differs every time the power is turned on. The amplified DC offset can be canceled by the newly obtained replica DC offset.
[0069]
These operations described above will be described more specifically with reference to FIGS.
FIG. 3 is a configuration diagram around the offset voltage control circuit 20a extracted from FIG. Since the offset voltage control circuit 20b has the same configuration as the offset voltage control circuit 20a and operates similarly, the offset voltage control circuit 20a will be described as a representative of both.
[0070]
As a specific configuration of the offset voltage control circuit 20a according to the first embodiment, for example, the one shown in FIG. 4 can be considered.
[0071]
In FIG. 4, 201a is an A / D converter, which inputs the output signal of the subtractor 16a and performs A / D conversion. A smoothing circuit 202a smoothes (averages) the output signal of the A / D converter 201a to reduce the influence of noise, and increases the amplified DC offset included in the output signal of the subtractor 16a. It detects with accuracy.
[0072]
An offset voltage calculation circuit 203a receives the amplified DC offset output from the smoothing circuit 202a and inputs a voltage E as a base of a replica DC offset necessary to cancel the DC offset to zero. _a Is calculated and output.
[0073]
Reference numeral 204a denotes a hold circuit, and an output signal (timing signal) from the timing control circuit 24 is H. _i In the case of level (through signal), the input signal is passed through and output as it is, but this timing signal is L _o When the level (hold signal) is changed, the input signal (voltage) immediately before that time is held (held). _o While the level signal is being received, the held voltage is continuously output.
[0074]
A D / A converter 205a converts the output of the hold circuit 204a, that is, the value (digital value) calculated by the offset voltage calculation circuit 203a into an analog voltage and outputs the analog voltage.
[0075]
In the offset voltage control circuit 20a configured as described above, the offset voltage calculation circuit 203a performs the voltage E as follows. _a Is calculated.
[0076]
When the power is on and the receiver is activated, the DC offset included in the baseband signal is x _a (V), and the variable gain amplifier 18a has a maximum gain of 80 (dB) based on the output of the voltage generator 22 (10 ^80/20 = 10 ^Four The offset voltage control circuit 20a is operated with a fixed gain of _a When the voltage of (V) is output, the DC offset included in the output signal of the subtractor 16a is Δ _a If it is (V), Formula (2) will be materialized.
Δ _a = X _a -10 ^Four ・ A _a (2)
[0077]
Here, the offset voltage calculation circuit 203a uses E as a voltage to cancel the detected DC offset to zero. _a (V) is calculated and the offset voltage control circuit 20a to a _a E instead of the voltage of (V) _a Since Δa (V) is canceled by 0 by outputting (V), Equation (3) is established in this state.
Δ _a = X _a -10 ^Four ・ E _a = 0 (3)
[0078]
When xa is eliminated using equations (2) and (3), equation (4) is obtained.
E _a = Δ _a / 10 ^Four + A _a (4)
[0079]
With the receiver turned on with the power turned on, the output voltage from the offset voltage control circuit 20a is a _a In the case of (V), Δ is an amplified DC offset included in the output signal of the subtractor 16a. _a If (V) is detected, the offset voltage calculation circuit 203a cancels the amplified DC offset included in the output signal of the subtractor 16a to zero. _a (V) can be obtained by calculation using equation (4). Further, the offset voltage calculation circuit 203a receives the voltage E obtained by the calculation via the hold circuit 204a. _a (V) is output.
[0080]
As described above, the receiver according to Embodiment 1 fixes the gains of the variable gain amplifiers 8a and 18a to the maximum gain within a short predetermined time immediately after the power is turned on and the receiver is started. The voltage E required to cancel the circuit-specific DC offset generated inside the circuit to zero. _a Is determined by the processing described above.
[0081]
When a certain period of time has elapsed after the start-up, the timing control circuit 24 outputs H _i L instead of level timing signal (through signal) _o A level timing signal (hold signal) is output, and the receiver receives a voltage E _a Is switched from the state of requesting to the normal reception state.
[0082]
The timing signal output from the timing control circuit 24 is H _i L from level _o At the time of switching to the level, the hold circuit 204a uses the voltage E calculated by the offset voltage calculation circuit 203a based on this timing signal. _a Is held as a voltage used in a normal reception state.
[0083]
In addition, the hold circuit 28a has the L _o While the level timing signal is being received, the held voltage E _a And continue to output a new voltage E _a Is not calculated.
[0084]
Therefore, in the normal reception state, the variable gain amplifier 18a already has the voltage E already obtained as described above and held in the hold circuit 204. _a (V) is always applied.
[0085]
By shifting to the normal reception state, the gain of the variable gain amplifier 8a also changes based on the control signal from the gain voltage generator 15 according to the power change of the reception signal received via the antenna 1, and is variable. The baseband signal that is the output signal of the gain amplifier 8a also includes an amplified DC offset unique to this circuit that is generated inside the circuit amplified according to the gain.
[0086]
Incidentally, the variable gain amplifier 18a has the same configuration as the variable gain amplifier 8a, and operates with the same gain as the variable gain amplifier 8a based on the control signal from the gain voltage generator 15 as in the conventional example. Therefore, the replica DC offset output from the variable gain amplifier 18a increases or decreases in accordance with the change in the gain, but this is an amount that can cancel the DC offset inherent to this circuit amplified by the variable gain amplifier 8a to zero. is there.
[0087]
Therefore, this circuit-specific amplified DC offset component is the voltage E described above. _a Is subtracted to 0 by the subtractor 16a using the signal amplified by the variable gain amplifier 18a. Therefore, in the normal reception state, the variable gain amplifiers 8a and 18a are controlled based on the control signal output from the gain control voltage generator 15. Even if the gain changes, the output of the subtractor 16a, that is, the amplitude of the input signal to the A / D converter 10a is maintained at a constant value from which the influence of the DC offset is eliminated.
[0088]
Voltage E _a Can be subtracted at the input point of the variable gain amplifier 8a to cancel the DC offset to zero at the input point of the variable gain amplifier 8a.
[0089]
However, in general, since the DC offset generated inside the variable gain amplifier changes with gain, the voltage E _a Is subtracted at the input point of the variable gain amplifier 8a, the DC offset generated in the low-pass filter 6a can be removed, but the DC offset generated in the variable gain amplifier 8a and changing with the gain cannot be removed.
[0090]
On the other hand, in the configuration of the first embodiment, the voltage E _a Is amplified by the variable gain amplifier 18a and then subtracted from the output signal of the variable gain amplifier 8a. Therefore, by using an amplifier element equivalent to the variable gain amplifier 8a for the variable gain amplifier 18a, the variable gain amplifier Since the amount of DC offset generated inside 8a and 18a changes corresponding to the change in gain, it is generated inside variable gain amplifier 8a together with the DC offset output from low-pass filter 6a, regardless of how the gain changes. The DC offset to be canceled can be offset to zero.
[0091]
Therefore, according to the first embodiment, since the replica DC offset is only subtracted from the baseband signal, the DC offset is removed without reducing the spectrum of the baseband signal as in the conventional configuration. it can. Further, it is possible to eliminate an offset voltage unique to this circuit generated inside the receiver circuit included in the baseband signal that causes a data error determination when determining the demodulated data to be output from the receiver. A receiver can be obtained.
[0092]
In the above description, the input signal of the offset voltage control circuit 20a has been described as the output signal of the subtractor 16a, but may be the output signal of the A / D converter 10a.
In this case, since the A / D converter 201a in the offset voltage control circuit 20a is substituted by the A / D converter 10a, the configuration is simplified.
[0093]
By the way, voltage E _a , E _b 2 may be performed not only within a certain period of time immediately after the power is turned on and the receiver is activated as described with reference to FIG. 2, but also during non-reception in a normal reception state.
[0094]
That is, the voltage E described above after the receiver is started immediately after the power is turned on. _a , E _b This setting operation may be intermittently performed in the non-reception state between the reception states of the receiver at the operation timing as shown in FIG.
[0095]
In recent mobile communication systems, a mode is used in which a plurality of users use the same frequency by time division, and communication is performed only in assigned time slots, so there is a communication idle time.
[0096]
Using this communication idle time, voltage E _a , E _b Perform the setting operation intermittently. This processing has an advantage that even if the DC offset amount included in the baseband signal changes due to temperature fluctuation or the like, the replica DC offset can flexibly follow the change.
[0097]
Similarly, in the case of Embodiments 2 to 3 to be described later, the replica DC offset may be obtained intermittently in the non-reception state between the reception states of the receiver.
[0098]
Embodiment 2. FIG.
As the configuration of the offset voltage control circuits 20a and 20b shown in FIG. 1 in the first embodiment, a replica DC offset may be generated by adopting the configuration described below in addition to the configuration shown in FIG. .
[0099]
FIG. 5 is a configuration diagram of the offset voltage control circuit 20a in the receiver (direct conversion receiver) according to the second embodiment. Since the offset voltage control circuits 20a and 20b have the same configuration, the offset voltage control circuit 20a will be described as a representative of both as in the first embodiment.
[0100]
In FIG. 5, as a new configuration in the second embodiment, 206a inputs the output signal of the subtractor 16a, determines whether the input signal is positive or negative, and outputs a binary signal “1” or “1” or It is a comparator that outputs any one of “0”.
[0101]
In addition, the output signal from the comparator 206a is smoothed (averaged) 207a, and the number of outputs of the output signals “1” and “0” is counted, and one of the counts is predetermined. When a certain threshold value is exceeded, a random walk filter (hereinafter referred to as RWF) that outputs the output signal that reaches the count number first, resets the count, and performs the count operation again.
[0102]
Further, 208a is a voltage control circuit that performs control to increase or decrease the voltage for canceling the DC offset to 0 based on the output signal of the RWF 207a.
[0103]
In the offset voltage control circuit 20a configured in this way, when the power source is turned on and the receiver is activated as in the first embodiment, the selection switch 23 receives the H from the timing control circuit 24. _i Since terminal B is selected based on the level timing signal, voltage E as shown below _a The operation of calculating is performed.
[0104]
The output signal of the subtracter 16a is input to the comparator 206a, and the positive / negative is discriminated. If the comparator 206a outputs a "1" signal when the input signal is positive and a "0" signal when the input signal is negative, the comparator 206a is positive DC amplified in the output signal of the subtractor 16a. When there is an offset, many signals of “1” are included in the output signal of the comparator 206a.
[0105]
Conversely, when there is a negative DC offset in the output signal of the subtractor 16, the output signal of the comparator 206a contains many "0" signals.
[0106]
The output of the comparator 206a is input to the RWF 207a and smoothed (averaged) to reduce the influence of noise. At the same time, the RWF 207a uses an internal counter (not shown) to count the number of “1” s in the input signal equal to or greater than a predetermined threshold value that precedes the count of the number of “0”. In this case, “1” is output to reset the internal counter.
[0107]
Conversely, when the count of the number “0” in the input signal becomes equal to or greater than a predetermined threshold value that precedes the count of the number “1”, “0” is output and the internal counter Repeat the operation to reset.
[0108]
Therefore, when the output signal from the subtractor 16a includes, for example, a positive DC offset, the output signal from the comparator 206a includes many signals of “1” as described above. Outputs a signal of “1”.
[0109]
When the output of the RWF 207a is “1”, the voltage control circuit 208a includes a large number of DC offsets that have not yet been canceled in the output signal of the subtractor 16a. Increase voltage).
[0110]
On the other hand, when the output of the RWF 207a is “0”, the DC offset is excessively canceled in the output signal of the subtractor 16a, so that the output value is decreased.
[0111]
The output voltage from the voltage control circuit 208a is input to the D / A converter 205a via the hold circuit 204a, converted into an analog voltage, and input to the variable gain amplifier 18a. Then, it is further amplified by the variable gain amplifier 18a and subtracted from the baseband signal amplified by the subtractor 16a.
[0112]
Therefore, when there is a positive DC offset in the output signal of the subtractor 16a, the output from the RWF 207a becomes a signal of “1”, so that the voltage control circuit 208a increases the output value. The output of the / A converter 206a also increases, and the output of the variable gain amplifier 18a increases.
That is, the replica DC offset amount subtracted from the baseband signal increases, and the positive DC offset included in the baseband signal approaches zero.
[0113]
On the other hand, when a negative DC offset is present in the output signal of the subtractor 16a, as in the above case, “0” is output from the comparator 205a and “0” is output from the RWF 207a. The voltage control circuit 208a decreases the output value. As a result, the output from the D / A converter 205a also decreases, and the output from the variable gain amplifier 18a decreases.
[0114]
That is, the replica DC offset subtracted from the baseband signal, which is the output from the variable gain amplifier 8a, decreases, and the negative DC offset included in the baseband signal approaches zero.
[0115]
Similar to the first embodiment, the above-described processes are amplified by being repeated while the Hi level signal is output from the timing control circuit 24, that is, in a short time after the receiver is activated. The amplified DC offset component included in the baseband signal converges to zero.
[0116]
Then, after a certain period of time has elapsed since startup, the timing signal output from the timing control circuit 24 is H _i L from level _o The receiver is switched to a level, and the receiver switches from a state for obtaining a replica DC offset to a normal reception state (a state in which the DC offset is canceled to 0).
[0117]
Operation after switching to the normal reception state (voltage voltage E _a , E _b Since the operations such as holding and DC offset cancellation are the same as those in the first embodiment, description thereof will be omitted.
[0118]
As described above, the configuration shown in FIG. 5 can also eliminate the influence of the DC offset included in the amplified baseband signal that is the output of the variable gain amplifier 8a, similarly to the configuration shown in FIG.
[0119]
Therefore, according to the second embodiment, since the replica DC offset is only subtracted from the baseband signal, the DC offset is removed without reducing the spectrum of the baseband signal as in the conventional configuration. it can. Further, it is possible to eliminate an offset voltage unique to this circuit generated inside the receiver circuit included in the baseband signal that causes a data error determination when determining the demodulated data to be output from the receiver. A receiver can be obtained.
[0120]
In the above description, the input signal of the offset voltage control circuit 20a has been described as the output signal of the subtractor 16a, but may be the output signal of the A / D converter 10a.
That is, the MSB (Most Significant Bit) of the output signal from the A / D converter 10a becomes “1” and “0” according to the positive / negative of the output of the subtractor 16a, and is the same as the output from the comparator 206a. Therefore, the comparator 206a is unnecessary and the configuration is simplified.
[0121]
Embodiment 3 FIG.
In the first and second embodiments, the generation of the replica DC offset in the non-reception state and the cancellation of the DC offset in the normal reception state to 0 may be performed with the following configuration.
[0122]
FIG. 6 is a configuration diagram of a receiver (direct conversion receiver) according to the third embodiment.
In FIG. 6, in the third embodiment, the variable gain amplifiers 18a and 18b used in the first and second embodiments are combined as one variable gain amplifier 18, and the offset voltage control circuits 20a and 20b also have one offset voltage. The control circuit 20 is configured as a whole.
[0123]
Reference numeral 34 denotes an average voltage detector which receives the output signals (output voltages) of the subtractors 16a and 16b and outputs the average voltage of these signals.
Then, the offset voltage control circuit 20 inputs the output from the average voltage detector 34 and sets the output voltage E so that the output from the average voltage detector 34 cancels out to zero as in the first and second embodiments. It comes to control.
[0124]
FIG. 8 is a configuration diagram around the offset voltage control circuit 20 extracted from FIG. As a specific configuration of the offset voltage control circuit 20 according to the third embodiment, for example, those already described in the first embodiment (FIG. 4) to the second embodiment (FIG. 5) can be considered.
Here, for convenience of explanation, the internal configuration of the offset voltage control circuit 20 will be specifically described by taking the example shown in FIG. 3 (Embodiment 1) as an example, and will be described with reference to FIGS.
[0125]
In the receiver offset voltage control circuit 20 according to the third embodiment, the voltage E is calculated as follows.
[0126]
After the power is turned on and the receiver is activated, the average voltage detector 34 inputs the outputs of the subtracters 16a and 16b and outputs the average voltage of these input signals.
That is, the output of the subtracter 16a is expressed as Δ _a , The output of the subtractor 16b is Δ _b When the output of the average voltage detector 34 is Δ, the average voltage detector 34 calculates Δ according to the equation (5) and outputs it.
Δ = (Δ _a + Δ _b ) / 2 (5)
The output of the average voltage detector 34 is input to the offset voltage control circuit 20.
[0127]
At the stage when the power is turned on and the receiver is activated, the DC offsets included in the two baseband signals input to the subtractors 16a and 16b are x _a , X _b (V) and the variable gain amplifier 18 has a maximum gain of 80 (dB) based on the output of the voltage generator 22 (10 ^80/20 = 10 ^Four ), And the offset voltage control circuit 20 outputs the voltage a (V), the DC offsets included in the output signals of the subtracters 16a and 16b are Δ _a , Δ _b If it is (V), Formula (6) will be materialized.
Δ _a = X _a -10 ^Four ・ A
Δ _b = X _b -10 ^Four ・ A (6)
[0128]
Where x _a = X _b Assuming that Δ from the equation (6) _a = Δ _b It becomes.
Therefore,
x = x _a = X _b , Δ = Δ _a = Δ _b (7)
Then, equation (8) is established.
Δ = x−10 ^Four ・ A (8)
[0129]
Here, the offset voltage calculation circuit calculates E (V) as a voltage that cancels the detected DC offset to 0, and replaces the voltage of a (V) from the offset voltage control circuit 20 with E (V). Since Δ (V) is output and canceled out to 0, Equation (9) is established in this state.
Δ = x−10 ^Four ・ E = 0 (9)
[0130]
When x is deleted using Equations (8) and (9), Equation (10) is obtained.
E = Δ / 10 ^Four + A (10)
[0131]
The offset voltage calculation circuit in the offset voltage control circuit 20 uses the value of the voltage Δ (V), which is a DC offset when the output voltage of the offset voltage control circuit 20 is a (V), as a voltage that becomes a replica DC offset. E (V) is calculated by equation (10).
[0132]
When the output voltage from the offset voltage control circuit 20 is a (V) at the stage where the power supply is turned on and the receiver is started, the output voltage of the average voltage detector 34 (the average of the output voltages of the subtractors 16a and 16b) If the average value Δ (V) of the DC offset is detected, the offset voltage calculation circuit cancels the amplified DC offset included in the outputs of the subtracters 16a and 16b to zero (E (V)). Can be obtained by calculation using equation (10).
[0133]
Further, the offset voltage calculation circuit outputs the calculated value to the variable gain amplifier 18 via the hold circuit 204a and the D / A conversion circuit 205a.
[0134]
As described above, in the receiver according to the third embodiment, similarly to the first embodiment, the variable gain amplifiers 8 and 18 are set within a short predetermined time immediately after the receiver is turned on and started. The voltage E necessary for canceling out the DC offset inherent in the circuit to zero is determined by the above-described processing.
[0135]
When a certain period of time has elapsed after the start-up, the timing control circuit 24 outputs H _i L instead of level timing signal _o A level timing signal is output, and the receiver switches from a state for obtaining a replica DC offset to a normal reception state.
[0136]
The timing signal output from the timing control circuit 24 is H _i L from level _o At the time of switching to the level, as in the first embodiment, the hold circuit of the offset voltage control circuit 20 uses the voltage E (V) calculated by the offset voltage calculation circuit based on the reception of the timing signal in the normal reception state. The voltage to be used is held.
[0137]
In addition, this hold circuit has this H _i While the level timing signal is received, the held voltage E (V) is supplied to the variable gain amplifier 18.
[0138]
Then, the replica DC offset output from the variable gain amplifier 18 is given to the subtracters 16a and 16b, respectively. Thus, the DC offset unique to the circuit as described above is the same as that of the first embodiment in the subtracters 16a and 16b, respectively. Can be offset.
[0139]
In the above description, the DC offsets included in the baseband signals output from the variable gain amplifiers 8a and 8b are equal (x _a = X _b ), Assuming that the assumption of Equation (7) holds.
[0140]
In this case, the DC offset in the output signals of the subtractors 16a and 16b can be completely canceled by zero by outputting the voltage E (V) calculated by the equation (10) through the D / A converter. .
[0141]
However, generally speaking, due to variations in element characteristics, etc., strictly speaking, x _a = X _b In many cases, the DC offset of the outputs of the subtracters 16a and 16b cannot be strictly offset to zero in the configuration of the third embodiment.
[0142]
But x _a And x _b If there is no great difference between the values, the DC offset can be made very small, and there is no practical problem.
[0143]
For example, x _a = 1 (V), x _b Considering the case of = 0.9 (V) is as follows.
The maximum gain of the variable gain amplifier 18 is 80 (dB) (10 ^80/20 = 10 ^Four ), If a = 50 (μV), Δ _a , Δ _b From equation (6)
Δ _a = 1-10 ^Four × 50 × 10 ^-6 = 0.5 (V)
Δ _b = 0.9-10 ^Four × 50 × 10 ^-6 = 0.4 (V)
It is.
[0144]
On the other hand, the output of the average voltage detector 34 is
Δ = (Δ _a + Δ _b ) /2=0.45 (V) (5)
It is.
[0145]
Therefore, when the offset voltage calculation circuit in the offset voltage control circuit 20 calculates the voltage E (V) by the equation (10),
E = 0.45 / 10 ^Four + 50 × 10 ^-6 = 95 (μV) (8)
It becomes.
[0146]
Accordingly, since the output of the offset voltage control circuit 20 is 95 (μV), the amplified DC offset included in the output signals of the subtracters 16a and 16b is 1-10, respectively. ^Four × 95 × 10 ^-6 = 0.05 (V)
0.9-10 ^Four × 95 × 10 ^-6 = -0.05 (V) (14)
Thus, the value is reduced to a sufficiently small value.
[0147]
It is apparent from the description of the second embodiment that the configuration of the offset voltage control circuit 20 may be that shown in FIG. Also in this case, the amplified DC offset included in the output signals of the subtracters 16a and 16b can be controlled to a sufficiently small value.
[0148]
As described above, in the third embodiment, the replica is based on the average value of the amplified DC offset values included in the two amplified baseband signals that are the outputs of the quasi-synchronized variable gain amplifiers 8a and 8b. Since it is configured to generate a DC offset, this configuration can be applied when there is no significant difference in the amount of DC offset of each output of the variable gain amplifiers 8a and 8b.
[0149]
Therefore, according to the third embodiment, since the replica DC offset is only subtracted from the baseband signal, the DC offset is removed without reducing the spectrum of the baseband signal as in the conventional configuration. it can. Further, it is possible to eliminate an offset voltage unique to this circuit generated inside the receiver circuit included in the baseband signal that causes a data error determination when determining the demodulated data to be output from the receiver. A receiver can be obtained.
[0150]
In addition, the circuit configuration can be simplified by reducing the number of variable gain amplifiers that output two replica DC offsets required in the first and second embodiments and the offset voltage control circuit to one. There is an advantage that you can.
[0151]
Embodiment 4 FIG.
For example, if the amplified DC offsets at the input points of the subtractors 16a and 16b are known in advance, power supplies for canceling these DC offsets to 0 are respectively applied to the input points of the variable gain amplifiers 18a and 18b. Thus, the influence of the DC offset may be excluded from the output signals of the subtracters 16a and 16b.
[0152]
FIG. 8 is a configuration diagram of a receiver (direct conversion receiver) according to the fourth embodiment.
In the receiver shown in FIG. 8, instead of the voltage control circuits 20a and 20b, fixed voltage generators 36a and 36b for generating fixed voltages that cancel out the respective DC offsets to zero are provided.
[0153]
The output voltages of the fixed voltage generators 36a and 36b are obtained by checking in advance the circuit-specific DC offset included in the output signals of the subtractors 16a and 16b when the receiver is in a normal reception state during the manufacturing process of the receiver. , Voltage E to cancel each DC offset to zero _a , E _b Respectively.
[0154]
In the first and second embodiments, a voltage E that becomes a replica DC offset by calculation _a , E _b However, in this case, since a replica DC offset that is fixed and set in advance in the manufacturing process of the receiver is given, it is possible to follow the fluctuation of the DC offset with respect to the temperature effect as compared with the first and second embodiments. Is not flexible, but does not require an offset voltage control circuit, and therefore has the advantage of simplifying the circuit configuration.
[0155]
9 corresponds to the fact that the configuration of the third embodiment simplifies the configuration of the first and second embodiments, and one variable gain amplifier 18 and one fixed replica DC offset generator 36 are used. The circuit configuration is simply configured.
[0156]
In the manufacturing process of the receiver, the output voltage of the fixed voltage generator 36 cancels the average of the DC offset inherent in this circuit included in the output signals of the subtractors 16a and 16b when the receiver is in a normal reception state to zero. The voltage E is determined as follows.
[0157]
Therefore, according to the fourth embodiment, since the replica DC offset is only subtracted from the baseband signal, the DC offset is removed without cutting the spectrum of the baseband signal as in the conventional configuration. it can. Further, it is possible to eliminate an offset voltage unique to this circuit generated inside the receiver circuit included in the baseband signal that causes a data error determination when determining the demodulated data to be output from the receiver. A receiver can be obtained.
[0158]
Further, the voltage E is obtained by calculation in the third embodiment, but here, since the voltage fixed in advance is given in the manufacturing process of the receiver, the fluctuation of the DC offset with respect to the temperature effect is compared with the third embodiment. 9 is not flexible, but when the DC offset amounts included in the two baseband signals are substantially equal, the offset voltage control circuit is not required, and the configuration of FIG. 9 can be applied, thereby simplifying the circuit configuration. There are advantages.
[0159]
【The invention's effect】
According to the present invention, in a receiver that receives a phase shift modulated radio signal and generates a baseband signal and amplifies the baseband signal according to the power of the radio signal, it is specific to the receiving circuit that receives the signal. A DC offset voltage output means for outputting the DC offset voltage of the baseband signal using means equivalent to at least the means for amplifying the baseband signal, and a DC offset voltage component generated from the received signal received by the receiving circuit and unique to the receiving circuit. DC offset voltage canceling means that cancels and outputs the DC offset voltage component output by the DC offset voltage output means from the baseband signal, so that a data error occurs when determining the demodulated data to be output from the receiver. This circuit occurs inside the receiver circuit included in the baseband signal that causes the judgment. It is possible to obtain a receiver capable of eliminating the intrinsic offset voltage.
[0160]
The DC offset voltage output means includes a DC offset voltage control circuit that determines the magnitude of the DC offset voltage component specific to the receiving circuit based on the output of the DC offset voltage canceling means in the non-calling state. A receiver capable of eliminating the circuit-specific offset voltage generated inside the receiver circuit included in the baseband signal that causes a data error determination when determining the demodulated data to be output from the receiver. Obtainable.
[0161]
The DC offset voltage output means is unique to the receiving circuit based on the average value of the output of the first DC offset voltage canceling means in the non-calling state and the output of the second DC offset voltage canceling means in the non-calling state. Since a DC offset voltage control circuit that determines the magnitude of the DC offset voltage component of the signal is included, it is included in the baseband signal that causes data error determination when determining the demodulated data to be output from the receiver. It is possible to obtain a receiver capable of eliminating the circuit-specific offset voltage generated inside the receiver circuit.
[0162]
The DC offset voltage control circuit includes an A / D converter for A / D converting the output result of the DC offset canceling means, a smoothing circuit for smoothing the output of the A / D converter, and an output of the smoothing circuit. DC offset voltage calculation circuit that calculates the magnitude of the DC offset voltage to a level that eliminates the influence of the DC offset voltage component unique to the receiver circuit from the voltage, and the DC offset voltage based on the through signal output from the timing control circuit A hold circuit that outputs the DC offset voltage calculated by the calculation circuit and holds and outputs the DC offset voltage calculated last by the DC offset voltage calculation circuit based on the hold signal output from the timing control circuit; Demodulated data to be output from the receiver because it is configured with a D / A converter that D / A converts the output The circuit-specific offset voltage generated in the circuit of a receiver included in the baseband signal that causes data error determination in data judgment can be obtained receiver capable of eliminating.
[0163]
The DC offset voltage control circuit counts the number of positive / negative determination results output from the determination circuit and the determination circuit that determines whether the output result of the DC offset canceling means is positive or negative, and the positive or negative count value is A random fork filter that outputs the result of determination when it reaches a predetermined number and repeats counting again, and a large amount that cancels the DC offset voltage component specific to the receiver circuit based on the output of the random fork filter In addition, the voltage adjustment circuit that determines the magnitude of the DC offset voltage and the DC offset voltage determined by the voltage adjustment circuit based on the through signal output from the timing control circuit and the hold signal output from the timing control circuit Based on the hold circuit that holds and outputs the DC offset voltage that the voltage regulator circuit last determined based on the Since it is configured with a D / A converter that performs D / A conversion on the output of the circuit, reception included in a baseband signal that causes data error determination when determining data of demodulated data to be output from the receiver It is possible to obtain a receiver capable of eliminating the circuit-specific offset voltage generated inside the circuit of the machine.
[0164]
In addition, since the timing control circuit outputs a through signal between immediately after the power is turned on and until a predetermined time, the cause of data error determination at the time of data determination of demodulated data to be output from the receiver Thus, it is possible to obtain a receiver capable of eliminating the circuit-specific offset voltage generated in the receiver circuit included in the baseband signal.
[0165]
In addition, since the timing control circuit outputs a hold signal during non-calling, the receiver included in the baseband signal that causes data error determination when determining data of demodulated data to be output from the receiver Thus, it is possible to obtain a receiver capable of eliminating the inherent offset voltage generated in the circuit.
[0166]
In addition, since the DC offset voltage output means is a fixed voltage generation means for generating a predetermined voltage that cancels the DC offset voltage component specific to the receiving circuit, the data of the demodulated data to be output from the receiver is determined. Thus, it is possible to obtain a receiver that can eliminate an offset voltage unique to this circuit generated in the receiver circuit included in the baseband signal that causes data error determination.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a receiver according to a first embodiment.
FIG. 2 is an explanatory diagram of a receiver according to the first embodiment.
FIG. 3 is an explanatory diagram of a receiver according to the first embodiment.
4 is an explanatory diagram of a receiver according to Embodiment 1. FIG.
FIG. 5 is an explanatory diagram of a receiver according to the second embodiment.
6 is an explanatory diagram of a receiver according to Embodiment 3. FIG.
7 is an explanatory diagram of a receiver according to Embodiment 3. FIG.
FIG. 8 is an explanatory diagram of a receiver according to the fourth embodiment.
FIG. 9 is an explanatory diagram of a receiver according to the fourth embodiment.
FIG. 10 is an explanatory diagram of a conventional direct conversion receiver.
FIG. 11 is an explanatory diagram of a conventional direct conversion receiver.
[Explanation of symbols]
16a, 16b subtractor, 18, 18a, 18b variable gain amplifier,
20, 20a, 20b offset voltage control circuit, 22 voltage generator,
23 selection switch, 24 timing control circuit,
201a A / D converter, 202a smoothing circuit,
203a offset voltage calculation circuit, 204a hold circuit,
205a D / A converter, 206a comparator,
207a random walk filter, 208a voltage control circuit,
34 Average voltage detector, 36, 36a, 36b, fixed voltage generator.

Claims (8)

In a receiver that receives a phase shift modulated radio signal to generate a baseband signal and amplifies the baseband signal in accordance with the power of the radio signal,
DC offset voltage output means for outputting a DC offset voltage specific to the receiving circuit for receiving the signal using means equivalent to at least the means for amplifying the baseband signal operating at the same gain ;
DC offset voltage canceling means for canceling and outputting the DC offset voltage component output from the DC offset voltage output means from the baseband signal generated from the received signal received by the receiving circuit and including the DC offset voltage component specific to the receiving circuit. And a receiver. The DC offset voltage output means includes a DC offset voltage control circuit that determines the magnitude of the DC offset voltage component specific to the receiving circuit based on the output of the DC offset voltage canceling means in a non-calling state. As described in the receiver. The DC offset voltage output means is a direct current specific to the receiving circuit based on the average value of the output of the first DC offset voltage canceling means in the non-calling state and the output of the second DC offset voltage canceling means in the non-calling state. 2. The receiver according to claim 1, further comprising a DC offset voltage control circuit that determines a magnitude of the offset voltage component. The DC offset voltage control circuit includes an A / D converter that performs A / D conversion on the output result of the DC offset canceling means, a smoothing circuit that smoothes the output of the A / D converter, and an output of the smoothing circuit A DC offset voltage calculation circuit for calculating the magnitude of the DC offset voltage so as to eliminate the influence of the DC offset voltage component specific to the receiving circuit from the voltage, and the DC offset based on the through signal output from the timing control circuit A hold circuit that outputs a DC offset voltage calculated by the voltage calculation circuit and holds and outputs the DC offset voltage calculated last by the DC offset voltage calculation circuit based on a hold signal output from the timing control circuit; 3. A D / A converter for D / A converting the output of the hold circuit, The receiver according to. The DC offset voltage control circuit counts the number of positive / negative determination results output from the determination circuit for determining the positive / negative of the output result of the DC offset cancellation means, and determines whether the positive or negative count value is in advance. A random fork filter that outputs the determination result of the reached one when it reaches a predetermined number and starts counting again, and a magnitude that cancels the DC offset voltage component specific to the receiving circuit based on the output of the random fork filter In addition, a voltage adjustment circuit for determining the magnitude of the DC offset voltage, and a DC offset voltage determined by the voltage adjustment circuit based on a through signal output from the timing control circuit and a hold output from the timing control circuit A hold circuit for holding and outputting the DC offset voltage last determined by the voltage adjustment circuit based on a signal A receiver according to claim 2 or 3, characterized in that the output of the hold circuit constituted by a D / A converter for converting D / A. 6. The receiver according to claim 4, wherein the timing control circuit outputs a through signal immediately after the power is turned on until a predetermined time. The receiver according to claim 4, wherein the timing control circuit outputs a hold signal during non-calling. 2. The receiver according to claim 1, wherein the DC offset voltage output means is a fixed voltage generation means for generating a predetermined voltage that cancels a DC offset voltage component specific to the receiving circuit.

Images