JP2004056458A - Amplitude shift keying receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an amplitude shift keying (ASK) which can discriminate data over a range from a very small input level to a large input level. <P>SOLUTION: A variable gain amplifier 2 for amplifying an ASK signal is provided. A detection circuit 3 for extracting a modulation signal component of the ASK signal from the output of the amplifier 2 is provided. A comparator 4 for waveform shaping and outputting the modulation signal component of the ASK signal is provided. A gain control circuit 5 for converting the output of the detection circuit 3 to a gain variable signal for the gain amplifier 2 and applying the converted signal to the amplifier 2 is provided. A gain control current distribution circuit 12 for distributing the output of the gain control circuit 5 in a constant ratio is provided. A threshold circuit 13 for making variable a first threshold voltage according to one output of the output of the comparator 4 and the distribution circuit 12 and applying the varied voltage to one input terminal of the comparator 4 is provided. A threshold circuit 14 for making variable a second threshold voltage according to the other output of the distribution circuit 12 and applying the varied voltage to the other input terminal of the comparator 4 is provided. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ASK receiver for receiving an ASK (Amplitude Shift Keying) signal, and more particularly to an ASK receiver used for a low-voltage receiver of a portable communication device.
[0002]
[Prior art]
2. Description of the Related Art In recent years, as the market for portable devices having a communication function has expanded, the demand for communication semiconductors operating at a low voltage has further increased.
[0003]
Hereinafter, an ASK receiver used for a conventional low-voltage semiconductor will be described.
[0004]
FIG. 8 is a block diagram showing a configuration of a conventional ASK receiver. In FIG. 8, an ASK signal is input from a signal input terminal 1. The variable gain amplifier 2 is an amplifier having a function of changing a gain by a gain control signal supplied from the outside, and is shown in a single-stage configuration in FIG. 8, but is a combination of an amplifier having a variable gain function and a fixed gain amplifier. It may be configured as a multi-stage amplifier.
[0005]
The input terminal of the variable gain amplifier 2 is connected to the signal input terminal 1, the output terminal of the variable gain amplifier 2 is connected to the input terminal of the detection circuit 3, and the first output terminal of the detection circuit 3 is connected to the comparator 4. A second output terminal of the detection circuit 3 is connected to the gain control circuit 5. The output terminal of the gain control circuit 5 is connected to the gain control terminal of the variable gain amplifier 2.
[0006]
The output terminal of the comparator 4 is connected to a signal output terminal 6 of the ASK receiver and to a threshold circuit 7. The output terminal of the threshold circuit 7 is connected to one input terminal (signal side) of the comparator 4 via an impedance element 8 such as a resistor. The threshold circuit 9 is connected to the other input terminal (reference side) of the comparator 4 via an impedance element 10 such as a resistor.
[0007]
The comparator 4, the threshold circuits 7, 9 and the impedance elements 8, 10 constitute a comparator 11 with hysteresis. In this case, the first threshold voltage supplied from the threshold circuit 7 to one input terminal of the comparator 4 changes in level to high or low according to the output of the comparator 4. The second threshold voltage applied from the threshold circuit 9 to the other input terminal of the comparator 4 is fixed.
[0008]
The operation of the ASK receiver configured as described above will be described below.
[0009]
The ASK signal is input to the signal input terminal 1 and is amplified by the variable gain amplifier 2 to a signal level at which a change in the amplitude of the ASK signal (High or Low of the ASK data) can be determined stably. The output of the variable gain amplifier 2 is such that the carrier component of the ASK signal is removed by the detection circuit 3 and the low frequency components (modulation signal component, data component) of the ASK signal are extracted, and then the comparator 4 can handle the output as a logic signal. The waveform is shaped and output from the signal output terminal 6.
[0010]
On the other hand, the signal at the second output terminal of the detection circuit 3 controls the gain of the variable gain amplifier 2 according to the output amplitude of the variable gain amplifier 2 so that even if the input signal level changes, the variable gain amplifier 2 Of the ASK signal so that the amplitude change (data) (High, Low) of the ASK signal can be determined stably. Generally, the signal at the second output terminal of the detection circuit 3 is often used as a DC component by further smoothing the signal at the first output terminal. That is, the signal at the second output terminal of the detection circuit 3 can be said to be an average amplitude detection signal corresponding to the average amplitude of the output of the variable gain amplifier 2.
[0011]
The signal at the second output terminal of the detection circuit 3 is converted into a gain control signal, that is, a gain control current, by the gain control circuit 5 and supplied to the variable gain amplifier 2, whereby the output signal level of the variable gain amplifier 2 is changed. This is a signal level at which the amplitude change of the ASK signal can be determined stably.
[0012]
The input of the comparator 4 has hysteresis by combining the first and second threshold voltages so that the noise component of the output of the detection circuit 3 is not superimposed on the output as chattering. The two threshold voltages are generated by the output (fixed voltage) of the threshold circuit 9 and the output of the threshold circuit 7 (the thresholds are changed according to the High and Low of the output of the comparator 4).
[0013]
Here, the generation process of the hysteresis will be described. The level of the first threshold voltage changes to high or low in accordance with the output of the comparator 4, so that the first threshold voltage becomes higher or lower than the second threshold voltage by a voltage corresponding to the hysteresis width. Therefore, the potential of one input terminal of the comparator 4 becomes higher or lower than the potential of the other input terminal by the hysteresis width in accordance with the output of the comparator 4.
[0014]
The output voltage of the detection circuit 3 is superimposed on the first threshold voltage applied to one input terminal of the comparator 4 so as to be added to the first threshold voltage. The voltage obtained by adding the voltage is compared with the second threshold voltage, and as described above, the first threshold voltage changes between high and low in accordance with the output of the comparator 4, so that the comparison operation of the comparator 4 has hysteresis. become.
[0015]
FIG. 9 shows a hysteresis voltage characteristic according to the conventional configuration. FIG. 9 shows the relationship between the hysteresis voltage (voltage difference between the signal side and the reference side) and the input of the ASK receiver, regardless of the change in the input level of the ASK receiver. This shows that the hysteresis voltage is constant. Here, the ASK receiver gives the reference side of the comparator 4 a hysteresis of + (positive) when the voltage on the signal side is positive, and conversely, gives a hysteresis of-(negative) when the voltage on the signal side is negative. By having it, chattering due to noise is prevented.
[0016]
[Problems to be solved by the invention]
However, in the above-described configuration, especially when receiving performance over a wide range of signal levels from a small input signal to a large signal is required at low voltage operation as in a portable device or the like, nonlinearity of a circuit causes a small signal input. Although the output amplitude of the detection circuit 3 with respect to the ASK signal and the S / N (signal-to-noise ratio) of the output of the detection circuit 3 are different between the case and the case of the large signal input, since the hysteresis of the comparator 4 is constant, The hysteresis width has to be set according to the detection output of either the signal input or the large signal input. As a result, there is a problem that the signal level range that can be received is restricted by either chattering of the output due to noise or inability to determine the data due to the detection output smaller than the hysteresis.
[0017]
SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned conventional problems and to provide an ASK receiver capable of reliably performing data discrimination from a small signal input level to a large signal input level without chattering. And
[0018]
[Means for Solving the Problems]
In order to achieve this object, an ASK receiver according to the first aspect of the present invention includes a variable gain amplifier that inputs and amplifies an ASK signal, and receives an output of the variable gain amplifier as an input and modulates a modulated signal component of the ASK signal. A detection circuit for extracting the average amplitude detection signal corresponding to the average amplitude of the output of the variable gain amplifier, and converting the average amplitude detection signal output from the detection circuit into a gain control signal and providing the same to the variable gain amplifier by ASK A gain control circuit for amplifying the ASK signal to a signal level at which a change in the amplitude of the signal can be determined stably, a comparator for shaping and outputting a modulated signal component of the ASK signal output from the detection circuit, and an output from the gain control circuit Control signal distribution circuit for distributing a gain control signal to two, data level of output of comparator and gain control signal distribution A first threshold value circuit that varies a first threshold value in accordance with one output of the path, applies the first threshold value to one input terminal of the comparator, and a second threshold value in accordance with the other output of the gain control signal distribution circuit. A second threshold circuit that varies a second threshold and applies the second threshold to the other input terminal of the comparator.
[0019]
According to this configuration, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and the first and second threshold values are determined based on one and the other outputs of the gain control signal distribution circuit. Since the first and second threshold values applied from the circuit to one and the other input terminals of the comparator are changed, the hysteresis width of the comparator can be changed according to the average amplitude detection signal output from the detection circuit. . As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[0020]
According to a second aspect of the present invention, there is provided an ASK receiver, comprising: a variable gain amplifier for inputting and amplifying an ASK signal; receiving an output of the variable gain amplifier as an input, extracting a modulated signal component of the ASK signal; A detection circuit that outputs an average amplitude detection signal corresponding to the average amplitude, and a change in the amplitude of the ASK signal is stably determined by converting the average amplitude detection signal output from the detection circuit into a gain control signal and supplying the gain control signal to a variable gain amplifier. A gain control circuit that amplifies the ASK signal to a signal level that can be obtained; a comparator that shapes and outputs a modulated signal component of the ASK signal output from the detection circuit; and a gain control signal that is output from the gain control circuit. The first threshold value is varied according to the gain control signal distribution circuit to be distributed and the data level of the output of the comparator. A first threshold voltage circuit applied to one input terminal of the comparator, and a second threshold value variable in accordance with one output of the gain control signal distribution circuit, and the second threshold value is applied to the other input terminal of the comparator And a second threshold circuit.
[0021]
According to this configuration, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and based on one output of the gain control signal distribution circuit, the gain control signal is distributed from the second threshold circuit to the other of the comparator. Is changed, the hysteresis width of the comparator can be changed according to the average amplitude detection signal output from the detection circuit. As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[0022]
According to a third aspect of the present invention, there is provided an ASK receiver, comprising: a variable gain amplifier for inputting and amplifying an ASK signal; receiving an output of the variable gain amplifier as an input, extracting a modulated signal component of the ASK signal, and obtaining an output of the variable gain amplifier. A detection circuit that outputs an average amplitude detection signal corresponding to the average amplitude, and a change in the amplitude of the ASK signal is stably determined by converting the average amplitude detection signal output from the detection circuit into a gain control signal and supplying the gain control signal to a variable gain amplifier. A gain control circuit that amplifies the ASK signal to a signal level that can be obtained; a comparator that shapes and outputs a modulated signal component of the ASK signal output from the detection circuit; and a gain control signal that is output from the gain control circuit. A gain control signal distribution circuit to be distributed; a data level of an output of the comparator and one output of the gain control signal distribution circuit. And a second threshold circuit that applies the first threshold to one input terminal of the comparator and a second threshold circuit that applies the second threshold to the other input terminal of the comparator. ing.
[0023]
According to this configuration, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and based on one output of the gain control signal distribution circuit, the first threshold circuit is switched to one of the comparators. Is changed, it is possible to change the hysteresis width of the comparator according to the average amplitude detection signal output from the detection circuit. As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
(First Embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
[0025]
FIG. 1 is a block diagram showing a basic configuration of the ASK receiver according to the first embodiment of the present invention. In FIG. 1, an ASK signal is input from a signal input terminal 1. The variable gain amplifier 2 is an amplifier having a function of changing the gain by an external gain control signal, and is shown in a single-stage configuration in FIG. 1, but a plurality of amplifiers having a variable gain function and a fixed gain amplifier are combined. It may be configured as a stage amplifier.
[0026]
The input terminal of the variable gain amplifier 2 is connected to the signal input terminal 1, the output terminal of the variable gain amplifier 2 is connected to the input terminal of the detection circuit 3, and the first output terminal of the detection circuit 3 is connected to the comparator 4. A second output terminal of the detection circuit 3 is connected to the gain control circuit 5. An output terminal of the gain control circuit 5 is connected to a gain control terminal of the variable gain amplifier 2 and a gain control current distribution circuit 12 as a gain control signal distribution circuit.
[0027]
In the gain control current distribution circuit 12, the output currents IX and IY divided into two at a fixed ratio are input to the threshold circuit 13 and the threshold circuit 14, respectively.
[0028]
FIG. 1 is a block diagram for explaining only the outline. The specific distribution of the output currents IX and IY will be described with reference to FIG. 2 showing a specific example. FIG. 2 shows a configuration in which the distribution ratio changes according to the amplitude level of the comparator input. ing.
[0029]
The output terminal of the comparator 4 is connected to the signal output terminal 6 of the ASK receiver and to the threshold circuit 13. An output terminal of the threshold circuit 13 is connected to one input terminal (signal side) of the comparator 4 via an impedance element 8 such as a resistor. The threshold circuit 14 is connected to the other input terminal (reference side) of the comparator 4 via the impedance element 10 such as a resistor.
[0030]
The comparator 4, the gain control current distribution circuit 12, the threshold circuits 13 and 14, and the impedance elements 8 and 10 constitute a comparator 15 with hysteresis.
[0031]
The operation of the ASK receiver configured as described above will be described below.
[0032]
The ASK signal is input to the signal input terminal 1 and is amplified by the variable gain amplifier 2 to a signal level at which a change in the amplitude of the ASK signal (High or Low of the ASK data) can be determined stably. The output of the variable gain amplifier 2 is designed so that the carrier component of the ASK signal is removed by the detection circuit 3 and the low-frequency component (modulated signal component or data component) of the ASK signal is taken out, and then the comparator 4 can handle it as a logic signal. The waveform is shaped and output from the signal output terminal 6.
[0033]
On the other hand, the signal at the second output terminal (average amplitude detection signal) of the detection circuit 3 controls the gain of the variable gain amplifier 2 according to the output amplitude of the variable gain amplifier 2 and the input signal level changes. However, the output signal level of the variable gain amplifier 2 acts so that the amplitude change (High or Low data) of the ASK signal can be determined stably. Generally, the signal at the second output terminal of the detection circuit 3 is often used as a DC component by further smoothing the signal at the first output terminal.
[0034]
The comparator 4 uses the output of the threshold circuit 13 and the output of the threshold circuit 14 as two input thresholds so that the noise component of the output of the detection circuit 3 is not superimposed on the output as chattering. And the other input terminal to provide hysteresis. The method of creating the hysteresis is the same as in the conventional example. The difference from the conventional example is how the threshold voltage changes.
[0035]
Here, the first threshold voltage output from the threshold circuit 13 changes according to the output level of the comparator 4 High or Low, and continuously or according to one output current IX of the gain control current distribution circuit 12. Changes intermittently. Further, the second threshold voltage output by the threshold circuit 14 changes continuously or intermittently according to the other output current IY of the gain control current distribution circuit 12. That is, since the output currents IX and IY of the gain control current distribution circuit 12 distribute the output (current) of the gain control circuit 5, when the output current IX increases (decreases), the output current IY decreases (increases). . As described above, since the output currents IX and IY differentially increase and decrease, the first and second threshold voltages are set to be continuous when the input level of the comparator 4 is low and to be intermittent when the input level is high (switching). Operation). Note that these specific operations will be described in detail in the second embodiment.
[0036]
As described above, the ASK receiver according to the present embodiment changes the hysteresis width of the comparator 15 with hysteresis in accordance with the output obtained by detecting the ASK signal, so that the S / N (signal-to-noise ratio) of the detection output is poor. The hysteresis width is increased so that noise such as chattering is not superimposed on the output at the signal level (noise is large), and the hysteresis width is reduced at the signal level where the detection output amplitude is reduced due to the restriction of the dynamic range of the circuit. Thereby, an excellent effect that an optimum data discrimination characteristic can be realized in the state of the detection output signal ranging from a small signal to a large signal can be obtained.
[0037]
As described above, according to the present embodiment, the signal input terminal 1 for inputting the ASK signal and the variable gain amplifier 2 connected to the signal input terminal 1 and having the function of varying the gain from the outside (in FIG. An amplifier having a variable gain function and a fixed gain amplifier may be combined to form a multi-stage amplifier). The output of the variable gain amplifier 2 is connected to the detection circuit 3, and the output of the detection circuit 3 is a comparator. 4. Connect to the gain control circuit 5. The output of the gain control circuit 5 is connected to a gain control terminal of the variable gain amplifier 2 and a gain control current distribution circuit 12. The output currents IX and IY distributed from the gain control current distribution circuit 12 are supplied to a threshold circuit 13 and a threshold circuit 14, respectively. The output of the comparator 4 is supplied to the signal output terminal 6 of the ASK receiver and is input to the threshold circuit 13. The output of the threshold circuit 13 is connected to one input terminal of the comparator 4 via an impedance element 8 such as a resistor. Since the threshold circuit 14 is connected to the other input terminal of the comparator 4 via the impedance element 10 such as a resistor, data can be determined from the minute input level to the large input level and suitable for each detection output characteristic. An ASK receiver can be realized.
[0038]
Although the first embodiment described the basic configuration and operation of the ASK receiver, each of the following embodiments is an embodiment that embodies the configuration of the embodiment of FIG. It shows a form.
[0039]
(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to the drawings. FIG. 2 is a block diagram illustrating a configuration of an ASK receiver according to the second embodiment. 2, an ASK signal is input from a signal input terminal 21. The variable gain amplifier 22 is an amplifier having a function of converting a gain by an external gain control signal. In the figure, the variable gain amplifier 22 is a two-stage variable gain amplifier (a variable gain first amplifier 22a and a variable gain second amplifier 22b). Although the configuration is shown, it may be configured by combining a variable gain amplifier and a fixed gain amplifier.
[0040]
The output signal VDin of the variable gain amplifier 22 is input to the detection circuit 23, and the output signal VDout1 (modulated signal component of the ASK signal) of the detection circuit 23 is input to the third amplifier 24 of the differential type, and the output signal of the detection circuit 23 is output. VDout2 (average amplitude detection signal) is input to the gain control circuit 25. The output of the third amplifier 24 is input to the input of the comparator 26 and the gain control current distribution circuit 27. The output current IAGC1 of the gain control circuit 25 is sent to the subtraction circuit 29 together with the fixed current I0 from the fixed current generation circuit 28. In the subtraction circuit 29, a current (I0-IAGC1) obtained by subtracting the output current IAGC1 of the gain control circuit 25 from the fixed current I0 is generated as a difference current IAGC0. The gain control current distribution circuit 27 includes transistors 27a to 27d.
[0041]
The difference current IAGC0 is supplied to the variable current source 30, and the currents IAMP1 and IAMP2 for controlling the gains of the first amplifier 22a and the second amplifier 22b are supplied from the variable current source 30 to the first amplifier 22a and the second amplifier 22b. Is extracted from the gain control terminal.
[0042]
The other output current IAGC2 of gain control circuit 25 is input to gain control current distribution circuit 27. The output currents IHys3 and IHys4 distributed by the gain control current distribution circuit 27 at a fixed ratio are input to the threshold circuits 31 and 32, respectively. The output current IHys3 and the output current IHys4 of the gain control current distribution circuit 27 are proportional to the other output current IAGC2 of the gain control circuit 25.
[0043]
The description of the distribution of the output currents IHys3 and IHys4 described below describes in detail the distribution of the output currents IX and IY in the first embodiment. Here, the output current IX of FIG. 1 corresponds to the output current IHys3 of FIG. 2, and the output current IY of FIG. 1 corresponds to the output current IHys4 of FIG.
[0044]
As shown in FIG. 2, an output (current) IAGC2 of the gain control circuit 25 is converted into an output current IHys3 by a differential circuit of a gain control current distribution circuit 27 which receives a comparator input (= output of the third amplifier 24) signal. Distribute to IHys4. Since the signal level of the input of the comparator 26 (= the output of the third amplifier 24) changes from a small level to a large level, IHys2 (２IAGC2) is distributed at a fixed ratio for each input level.
[0045]
In FIG. 2, if there are no output currents IHys3 and IHys4, the threshold voltage VTH2 is a fixed voltage determined only by the resistance voltage division, and the threshold voltage VTH1 is H and L of the comparator output, and the threshold voltage VTH2 is positive and negative with respect to the threshold voltage VTH2. Minute change.
[0046]
In the present invention, the hysteresis width is changed by changing the current flowing through the impedance elements R1 to R5 by the output currents IHys3 and IHys4.
[0047]
As an example, when the comparator input has a large amplitude and the current IHys2 is distributed to almost 100% to the output current IHys3 (or IHys4), when the IHys1 flows and the threshold voltage VTH1 is on the minus side, the gain control current distribution circuit 27 (That is, the base on the output current IHys4 side of the differential circuit is high), the threshold voltage VTH2 also changes to the negative side by the voltage drop due to the output current IHys4. The hysteresis width on the minus side can be made smaller than when IHys3 and IHys4 are not supplied.
[0048]
The output current IAGC2 of the gain control circuit 25 changes according to the signal input level. The output of the third amplifier 24 also changes according to the signal input level because it is before comparison. The gain control signal distribution circuit 27 has a configuration of a differential amplifier, and outputs a current IHys2 proportional to the output current IAGC2 to an output current IHys3 according to the input (= output of the third amplifier 24) amplitude of the gain control signal distribution circuit 27. It is distributed to the current IHys4.
[0049]
If the output amplitude of the third amplifier 24 is very small, then IHys3ＨIHys4 ≒ IHys2 / 2, and if the output amplitude of the third amplifier 24 is large, the output currents IHys3 and IHys4 according to the level of the output (amplitude). Are distributed in large proportions. The ratio increases as the amplitude of the third amplifier 24 increases in a signal level range where the gain control signal distribution circuit 27 does not saturate. In the above-described first embodiment, this portion is shown in a block diagram, but the second embodiment is described as a specific circuit.
[0050]
As described above, when the signal input is small, the output of the third amplifier 24 is also small, so that the gain control signal distribution circuit 27 flows the output currents IHys3 and IHys4 as the current obtained by simply dividing the current IHys2 into almost two. . On the other hand, as the signal input increases, the current IHys2 (∝IAGC2) changes, and the output amplitude of the third amplifier 24 also increases. Therefore, the distribution ratio of the output currents IHys3 and IHys4 distributed from the current IHys2 also increases. growing.
[0051]
If the differential circuit of the gain control signal distribution circuit 27 has such a large input that it operates completely as a switch, the output current IHys3 and the output current IHys4 alternately switch between IHys2 × 100% and IHys2 × 0%. However, in the present invention, since the distribution ratio between “IHys2 × 50%” and “IHys2 × 100% or 0%” is also used, the distribution is expressed as a constant (predetermined) ratio.
[0052]
That is, as described above, when the output level of the third amplifier 24 is low, IHys3 ≒ IHys4 ≒ IHys2 / 2. When the output level of the third amplifier 24 is large and the differential circuit of the gain control signal distribution circuit 27 performs a complete switching operation, IHys3 ≒ IHys2, IHys4 ≒ 0 and IHys3 ≒ 0, IHys4 ≒ IHys2 3 The switching is performed in accordance with the level of the output of the amplifier 24. In the present invention, since the signal can be used between a small signal and a large signal, IHys3 (IHys4) is in the range between IHys2 × 0% and IHys2 × 100%. In order to be a value, the expression is not limited to “switch” or “intermittent”.
[0053]
Each of the threshold circuit 31 and the threshold circuit 32 includes a reference voltage VR and impedance elements R1 to R5 such as resistors. The output of the comparator 26 is supplied to a signal output terminal 35 of the ASK receiver, and is also connected to a threshold circuit 31 via a current source 36, so that the output of the comparator 26 is subjected to hysteresis control by High and Low. The first threshold voltage VTH1 output from the threshold circuit 31 is input to one input terminal (signal side) of the third amplifier 24 via the first buffer 33 and an impedance element RB1 such as a resistor. The second threshold voltage VTH2 output from the threshold circuit 32 is input to the other input terminal (reference side) of the third amplifier 24 via the second buffer 34 and an impedance element RB2 such as a resistor.
[0054]
The operation of the ASK receiver configured as described above will be described below.
[0055]
The ASK signal is input to the signal input terminal 21, and is amplified by the first amplifier 22a and the second amplifier 22b constituting the variable gain amplifier 22 to a signal level at which a change in the amplitude of the ASK signal (High or Low of the ASK data) can be determined stably. Is done. From the output of the variable gain amplifier 22, the carrier component of the ASK signal is removed by the detection circuit 23, and the low frequency component (modulated signal component or data component) of the ASK signal is extracted. The output VDout2 of the detection circuit 23 is input to the gain control circuit 25, and after the difference current IAGC0 from the fixed current I0 is generated, the variable currents IAMP1 and IAMP2 from the variable current source 30 are input to the gain control terminal of the variable gain amplifier 22. Then, even when the input signal level changes, the amplitude change (High or Low data) of the ASK signal is set to a signal level that can be stably determined.
[0056]
On the other hand, the output VDout1 of the detection circuit 23 is input to the third amplifier 24 provided at the input of the comparator 26. The signal amplified by the third amplifier 24 to a level at which the differential circuit (transistors 27c and 27d) of the gain control current distribution circuit 27 can be switched is output after the waveform is shaped by the comparator 26 so that it can be handled as a logic signal.
[0057]
The gain control current distribution circuit 27 is in a state in which the other output current IAGC2 of the gain control circuit 25 or the current IHys2 proportional to the other output current IAGC2 flows to the output current IHys3 side in accordance with the differential output of the third amplifier 24. And a state in which more current flows to the output current IHys4 side. This is because the ratio of the on-side current to the off-side current of the differential circuit of the gain control current distribution circuit 27 changes depending on the magnitude of the amplitude of the comparator input. That is, the current IHys2 is not always switched between the output current IHys3 side and the output current IHys4 side at 100% / 0% at the fixed ratio according to the magnitude of the amplitude of the comparator input. .
[0058]
Each of the threshold circuit 31 and the threshold circuit 32 includes a reference voltage VR and impedance elements R1 to R5 such as resistors. Then, the comparator 26 is provided with a hysteresis characteristic so that the noise component of the output of the detection circuit 23 is not superimposed on the output of the comparator 26 as chattering. Therefore, the variable current IHys1 is turned on and off by the output High and Low of the comparator 26, the variable current IHys1 is turned off when the output of the comparator 26 is High, and the variable current IHys1 is turned on when the output of the comparator 26 is Low. As a result, the first threshold voltage VTH1 output from the threshold circuit 31 is switched, and the voltage difference becomes a hysteresis. The threshold circuits 31 and 32 also switch the first and second threshold voltages VTH1 and VTH2 according to the output currents IHys3 and IHys4 of the gain control current distribution circuit 27.
[0059]
By switching between a state in which the current IHys2 proportional to the current IAGC2 flows as the output current IHys3 or a state in which the current IHys4 flows as the output current IHys4 in accordance with the output High and Low of the comparator 26, the first threshold voltage which is the output of the threshold circuit 31 VTH1 or the second threshold voltage VTH2 output from the threshold circuit 32 is changed. In the case where the output current IHys3 (high) flows when the output of the comparator 26 is High and the output current IHys4 flows (high) when the output of the comparator 26 is Low, the hysteresis voltage width due to only the variable current IHys1 is smaller than the hysteresis voltage width. Work to make it smaller. That is, the hysteresis control proportional to the current IAGC2 is performed by switching and supplying the output currents IHys3 and IHys4.
[0060]
A first threshold voltage VTH1, which is an output of the threshold circuit 31, and a second threshold voltage VTH2, which is an output of the threshold circuit 32, are respectively a first buffer 33, a second buffer 34 (or an emitter follower) and an impedance element RB1. , RB2, a variable DC bias which is a threshold value of the comparator 37 with hysteresis is applied to two input terminals of the third amplifier 24.
[0061]
The impedance elements RB1 and RB2 are unnecessary depending on the circuit configuration. Since the current IAGC2 changes continuously (or intermittently) according to the input level of the ASK receiver, the hysteresis width due to the current IHys1, the output current IHys3, and the output current IHys4 is continuously (or alternatively) depending on the input level of the ASK receiver. Changes intermittently).
[0062]
3 shows an example of the input / output characteristics of the detection circuit 23, FIG. 4 shows an example of the input / output characteristics of the gain control current, and FIG. 5 shows an example of the input / output characteristics of the hysteresis width according to the present invention. The hysteresis is such that the reference side of the third amplifier 24, which is the input side of the comparator 26, has + (positive) hysteresis when the voltage on the signal side is positive and − (negative) when the voltage on the signal side is negative. To prevent chattering due to noise. As can be seen from FIG. 5, the hysteresis width decreases as the input level of the ASK receiver increases.
[0063]
As described above, according to the present embodiment, the hysteresis width of the comparator with hysteresis 37 is changed according to the input level of the ASK receiver. For example, when the S / N of the detection output is low (the noise is large) when the input of the ASK receiver is very small and the output amplitude of the detection circuit 23 becomes small due to the dynamic range of the circuit when the input is large, the hysteresis is provided at the minute input level. By increasing the hysteresis width of the comparator 37 and decreasing the hysteresis width at a large input, it is possible to realize an ASK receiver capable of discriminating data suitable for each detection output characteristic from a minute input level to a large input level. it can.
[0064]
(Third embodiment)
Hereinafter, a third embodiment of the present invention will be described with reference to the drawings. FIG. 6 shows a specific configuration of the ASK receiver according to the third embodiment.
[0065]
6 differs from FIG. 2 only in that the output current IHys3 of the gain control current distribution circuit 27 is connected to the power supply Vcc without being connected to the threshold circuit 31, and a common description is omitted.
[0066]
The comparator of the present invention is a hysteresis comparator in which the threshold voltage VTH1 changes to plus or minus with respect to a reference voltage (threshold voltage VTH2 in the figure), and changes the output current IAGC2 of the gain control circuit 25 according to the level of the comparator input. After switching, it is necessary to connect to the threshold circuits 31 and 32. Indeed, the other distributed current does not lead to the threshold circuits 31 and 32, but it is simple and necessary to use a differential circuit to switch according to the level of the input of the comparator as described above. The configuration is the same as that of the distribution of the gain control signal.
[0067]
In the ASK receiver configured as described above, only one of the + or-hysteresis is varied according to the input level of the ASK receiver.
[0068]
FIG. 7 shows an example of input / output characteristics of the hysteresis width according to the third embodiment of the present invention.
[0069]
As described above, according to the present embodiment, in accordance with the characteristics of the output of the detection circuit 23 depending on the input level of the ASK receiver, for example, the hysteresis on the + side is made constant at almost 0 V, and only the hysteresis on the-side is set. Can be made variable with respect to the input level, and an ASK receiver capable of discriminating data suitable for each detection output characteristic from a minute input level to a large input level can be realized.
[0070]
Contrary to the above, a configuration in which the output current IHys4 of the gain control current distribution circuit 27 is connected to the power supply Vcc without connecting to the threshold circuit 32 can be considered. In this case, the threshold voltage of the threshold circuit 32 is fixed. In this case, the same effect as above can be obtained.
[0071]
【The invention's effect】
As described above, according to the ASK receiver according to claim 1 of the present invention, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and one of the gain control signal distribution circuits and Since the first and second threshold values applied to one and the other input terminals of the comparator from the first and second threshold circuits are changed based on the other output, the average amplitude detection output from the detection circuit is detected. The hysteresis width of the comparator can be changed according to the signal. As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[0072]
According to the ASK receiver according to claim 2 of the present invention, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and based on one output of the gain control signal distribution circuit, Since the second threshold value applied from the second threshold circuit to the other input terminal of the comparator is changed, the hysteresis width of the comparator can be changed according to the average amplitude detection signal output from the detection circuit. As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[0073]
According to the ASK receiver according to claim 3 of the present invention, the gain control signal output from the gain control circuit is divided into two by the gain control signal distribution circuit, and based on one output of the gain control signal distribution circuit, Since the first threshold value applied from the first threshold circuit to one input terminal of the comparator is changed, the hysteresis width of the comparator can be changed according to the average amplitude detection signal output from the detection circuit. As a result, data discrimination suitable for each detection output characteristic can be performed from the minute input level to the large input level.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an ASK receiver according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a specific configuration of an ASK receiver according to a second embodiment of the present invention.
FIG. 3 is a characteristic diagram illustrating an example of input / output characteristics of a detection circuit of an ASK receiver according to a second embodiment of the present invention.
FIG. 4 is a characteristic diagram showing an example of input / output characteristics of a gain control current of an ASK receiver according to a second embodiment of the present invention.
FIG. 5 is a characteristic diagram showing an example of input / output characteristics of a hysteresis voltage of an ASK receiver according to a second embodiment of the present invention.
FIG. 6 is a block diagram illustrating a specific configuration of an ASK receiver according to a third embodiment of the present invention.
FIG. 7 is a characteristic diagram showing an example of input / output characteristics of a hysteresis voltage of an ASK receiver according to a third embodiment of the present invention.
FIG. 8 is a block diagram showing a configuration of an ASK receiver in a conventional example.
FIG. 9 is a characteristic diagram illustrating an example of input / output characteristics of a hysteresis voltage of a conventional ASK receiver.
[Explanation of symbols]
1 signal input terminal
2 Variable gain amplifier
3 Detection circuit
4 Comparator
5 Gain control circuit
6 Signal output terminal
8 Impedance element
10 Impedance element
12 Gain control current distribution circuit
13 threshold circuit
14 threshold circuit
15 Comparator with hysteresis
21 signal input terminal
22 Variable gain amplifier
23 Detection circuit
24 Third amplifier
25 Gain control circuit
26 Comparator
27 Gain control current distribution circuit
28 Fixed current generation circuit
29 Subtraction circuit
30 Variable current source
31 threshold circuit
32 threshold circuit
33 buffers
34 buffers
35 signal output terminal
36 current source
37 Comparator with hysteresis

Claims (3)

A variable gain amplifier that receives and amplifies the ASK signal;
A detection circuit that receives an output of the variable gain amplifier as an input, extracts a modulation signal component of the ASK signal, and outputs an average amplitude detection signal corresponding to an average amplitude of the output of the variable gain amplifier;
A gain control circuit for converting the average amplitude detection signal output from the detection circuit into a gain control signal and applying the converted signal to the variable gain amplifier to amplify the ASK signal to a signal level at which the amplitude change of the ASK signal can be determined stably. When,
A comparator for shaping the waveform of the modulated signal component of the ASK signal output from the detection circuit and outputting the shaped signal;
A gain control signal distribution circuit that distributes the gain control signal output from the gain control circuit into two,
A first threshold circuit that varies a first threshold value according to a data level of an output of the comparator and one output of the gain control signal distribution circuit, and applies the first threshold value to one input terminal of the comparator; When,
A second threshold circuit that varies a second threshold value according to the other output of the gain control signal distribution circuit and applies the second threshold value to the other input terminal of the comparator. A variable gain amplifier that receives and amplifies the ASK signal;
A detection circuit that receives an output of the variable gain amplifier as an input, extracts a modulation signal component of the ASK signal, and outputs an average amplitude detection signal corresponding to an average amplitude of the output of the variable gain amplifier;
A gain control circuit for converting the average amplitude detection signal output from the detection circuit into a gain control signal and applying the converted signal to the variable gain amplifier to amplify the ASK signal to a signal level at which the amplitude change of the ASK signal can be determined stably. When,
A comparator for shaping the waveform of the modulated signal component of the ASK signal output from the detection circuit and outputting the shaped signal;
A gain control signal distribution circuit that distributes the gain control signal output from the gain control circuit into two,
A first threshold circuit that varies a first threshold value according to a data level of an output of the comparator, and applies the first threshold value to one input terminal of the comparator;
An ASK receiver comprising: a second threshold circuit that varies a second threshold value according to one output of the gain control signal distribution circuit, and applies the second threshold value to the other input terminal of the comparator. A variable gain amplifier that receives and amplifies the ASK signal;
A detection circuit that receives an output of the variable gain amplifier as an input, extracts a modulation signal component of the ASK signal, and outputs an average amplitude detection signal corresponding to an average amplitude of the output of the variable gain amplifier;
A gain control circuit for converting the average amplitude detection signal output from the detection circuit into a gain control signal and applying the converted signal to the variable gain amplifier to amplify the ASK signal to a signal level at which the amplitude change of the ASK signal can be determined stably. When,
A comparator for shaping the waveform of the modulated signal component of the ASK signal output from the detection circuit and outputting the shaped signal;
A gain control signal distribution circuit that distributes the gain control signal output from the gain control circuit into two,
A first threshold circuit that varies a first threshold value according to a data level of an output of the comparator and one output of the gain control signal distribution circuit, and applies the first threshold value to one input terminal of the comparator; When,
A second threshold circuit for applying a second threshold to the other input terminal of the comparator.

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