JP2021016028A - Ad conversion device, ad conversion method, and signal processing apparatus - Google Patents

Abstract

To prevent the influence of variations of dither signals to stabilize the AD conversion performance in an AD conversion device of an oversampling system.SOLUTION: An AD conversion device (10) comprises: a dither signal generation unit (1) that generates a dither signal added to an analog input signal; an AD conversion unit (3) that performs processing of converting the analog input signal added with the dither signal into a digital value; and an averaging processing unit (5) that calculates the average value of the digital values obtained by the AD conversion unit performing the conversion processing a plurality of times within a predetermined period, and outputs the average value as a digital signal after the AD conversion with the predetermined period as a sampling period. Within the predetermined period, the value of the dither signal varies within a range corresponding to a value that is set within a range of 6 LSB or more and 260 LSB or less.SELECTED DRAWING: Figure 1

Description

The present invention relates to an AD converter that performs oversampling.

For example, as described in Patent Documents 1 to 3, in an oversampling type AD converter, a dither signal is added to an input signal in order to improve the output S / N.

Further, it is known that in an oversampling type AD converter, the resolution and S / N are improved by performing an averaging process on a large number of AD conversion data.

Japanese Unexamined Patent Publication No. 2014-7518 (published on January 16, 2014) Japanese Patent No. 4648996 (issued on March 9, 2011) Japanese Patent No. 6-104751 (published on April 15, 1994)

In the prior art of adding a dither signal to an input signal as described above, the magnitude of the dither signal is important. However, these prior arts do not clearly provide design guidelines for how large the dither signal should be. For this reason, the expected improvement effect is often not obtained.

Theoretically, the amplitude of the dither signal is optimally 2LSB (± 1LSB). However, in reality, it is difficult to realize a circuit or environment in which a very small voltage corresponding to 1 LSB is accurately added to the input signal without error each time at a practical cost.

When the dither signal is less than 1 LSB, it is expected that the effect of improving the resolution is small or the resolution is not improved at all. Also, if the dither signal exceeds 1 LSB, it is unpredictable how the resolution will be improved. Therefore, if the amplitude of the dither signal varies, the resolution is affected by the amplitude, and there is a disadvantage that stable AD conversion performance cannot be obtained.

One aspect of the present invention is an object of an oversampling type AD conversion apparatus, in which the influence of variation in dither signals is suppressed and the AD conversion performance is stabilized.

In order to solve the above problems, the AD conversion device according to one aspect of the present invention has a dither signal generation unit that generates a dither signal to be added to the analog input signal, and the analog input signal to which the dither signal is added. An AD conversion unit that performs a process of converting to a digital value and an average value of the digital values obtained by performing the conversion process by the AD conversion unit a plurality of times within a predetermined period are calculated, and the predetermined period is sampled. It is provided with an averaging processing unit that outputs as a digital signal after AD conversion, and the value of the dither signal is in a range of amplitude corresponding to a value set in a range of 6 LSB or more and 260 LSB or less in the predetermined period. fluctuate.

In order to solve the above problems, the AD conversion method according to one aspect of the present invention includes a dither signal generation step of generating a dither signal to be added to an analog input signal, and the analog input signal to which the dither signal is added. An AD conversion step that performs a process of converting to a digital value and an average value of the digital values obtained by performing the conversion process in the AD conversion step a plurality of times within a predetermined period are calculated, and the predetermined period is sampled. Including the averaging process step of outputting as a digital signal after AD conversion, the value of the dither signal is in the range of amplitude corresponding to the value set in the range of 6 LSB or more and 260 LSB or less in the predetermined period. fluctuate.

According to the above configuration, the maximum error of AD conversion can be suppressed to 2LSB or less. Therefore, even if the amplitude of the dither signal varies or has an error, the effect on the resolution is small. Therefore, stable AD conversion performance can be obtained at a practical cost.

The value of the dither signal may fluctuate by a value set in a range of amplitude corresponding to 12 LSB or more and 120 LSB or less in the predetermined period.

According to the above configuration, the maximum error of AD conversion can be suppressed to 1 LSB or less. Therefore, the AD conversion performance can be further stabilized.

In order to solve the above problems, the signal processing device according to one aspect of the present invention includes any of the above AD conversion devices and a signal output unit that outputs a digital signal output from the AD conversion device. ing.

According to the above configuration, it is possible to output a digital signal having high resolution and improved S / N.

According to one aspect of the present invention, in the oversampling type AD conversion device, the influence of the variation of the dither signal can be suppressed and the AD conversion performance can be stabilized.

It is a block diagram which shows the structure of the signal processing apparatus which concerns on one Embodiment of this invention. It is a flowchart which shows the procedure of AD conversion processing by the AD conversion apparatus in the said signal processing apparatus. It is a figure which shows the relationship between the waveform example of the dither signal used in the AD conversion apparatus, the frequency distribution of a signal level, and AD conversion accuracy. It is a figure which shows the relationship between the amplitude of the noise (dither signal) generated by the AD conversion apparatus, and the maximum error after AD conversion.

[Embodiment]
Hereinafter, embodiments according to one aspect of the present invention (hereinafter, also referred to as “the present embodiment”) will be described with reference to the drawings.

§1 Application example An example of a situation in which the present invention is applied will be described with reference to FIG.

FIG. 1 is a block diagram showing a schematic configuration of a signal processing device 100 according to the present embodiment.

As shown in FIG. 1, the signal processing device 100 is a device such as an analog input unit that takes in an analog signal, converts it into a digital signal, and outputs the signal, and includes an AD conversion device 10 and a signal output unit 20. ing. The AD conversion device 10 converts an analog input signal (analog input signal) whose detection value output from the sensor 30 is input via the amplifier (indicated by AMP in the figure) 40 into a digital signal. The signal output unit 20 outputs a digital signal to a PLC (Programmable Logic Controller). The sensor 30 detects various physical quantities such as temperature and pressure.

As described above, the signal processing device 100 is not limited to the device that converts the captured analog input signal into a digital signal and outputs the signal to the PLC. For example, the signal processing device 100 may be a temperature control unit having a temperature control function (including a control unit and a control output unit for a control target (heater or the like)). Further, the signal processing device 100 may be a digital panel meter which is a display device which converts the captured analog input signal into a digital signal and numerically displays the result of performing a predetermined process on the digital signal.

The AD conversion device 10 includes a dither signal generation unit 1, an adder 2, an AD conversion unit 3, a data storage unit 4, an averaging processing unit 5, and a cycle control unit 6.

The dither signal generation unit 1 generates a dither signal to be added to the analog input signal. The adder 2 adds the dither signal to the analog input signal. The value of the dither signal fluctuates in the range of amplitude corresponding to the value set in the range of 6 LSB (Least Significant Bit) or more and 260 LSB or less in a predetermined period.

The AD conversion unit 3 performs a process of converting an analog input signal to which a dither signal is added into a digital value.

The averaging processing unit 5 calculates the average value of the digital values obtained by performing the conversion processing by the AD conversion unit 3 a plurality of times within a predetermined period. Further, the averaging processing unit 5 outputs the calculated digital average value as a digital signal after AD conversion having a predetermined period as a sampling cycle.

The periodic control unit 6 controls the operations of the data storage unit 4 and the averaging processing unit 5 that are periodically performed in association with the AD conversion processing that is performed a plurality of times by the AD conversion unit 3.

The AD conversion device 10 can suppress the maximum error of AD conversion to a practical level by using a dither signal having a voltage amplitude corresponding to 6 LSB or more and 260 LSB or less in a predetermined period. The details of the error reduction effect will be described later.

§2 Configuration example A configuration example of the AD conversion device 10 according to the embodiment will be described with reference to FIG.

The dither signal generation unit 1 generates a dither signal having an amplitude of a preset amplitude set value (voltage value). As the dither signal, a signal having a waveform such as a triangular wave, a sawtooth wave, a sine wave, or random noise is used. The dither signal generation unit 1 generates a dither signal voltage value that changes according to the waveform in the amplitude range for each of a plurality of AD conversion processes performed by the AD conversion unit 3 with respect to the voltage value of the analog input signal. .. Further, the dither signal not only fluctuates in value in the range of amplitude corresponding to 6 LSB or more and 260 LSB or less described above in a predetermined period, but more preferably, the dither signal has an amplitude corresponding to 12 LSB or more and 120 LSB or less in a predetermined period. The value may fluctuate within the range. The setting of the amplitude of the dither signal will be described in detail later.

The adder 2 adds the voltage of the dither signal generated by the dither signal generation unit 1 to the voltage of the analog input signal. More specifically, the adder 2 adds the changing voltage value output from the dither signal generation unit 1 to the voltage value of the analog input signal for each of the plurality of AD conversion processes performed by the AD conversion unit 3.

The AD conversion unit 3 is a main unit of the AD conversion device 10 that converts a voltage (analog value) input from the adder 2 into a digital value. The AD conversion unit 3 is composed of various types of AD converters such as a double integral type and a sequential comparison type. The AD conversion unit 3 realizes oversampling by performing AD conversion processing a plurality of times (the average number of times that the averaging processing unit 5 performs averaging processing) on the voltage value of the analog input signal.

The data storage unit 4 stores a plurality of digital values of the voltage values of the analog input signals output from the AD conversion unit 3 as data. More specifically, the data storage unit 4 adds digital values that are sequentially input. The data storage unit 4 resets the added digital value (total value) by a reset signal described later from the cycle control unit 6. The data storage unit 4 is composed of a memory, a register, and the like.

When the number of times the AD conversion is executed by the AD conversion unit 3 reaches a preset number of times, the cycle control unit 6 outputs a reset signal to the data storage unit 4. Therefore, the cycle control unit 6 includes a counter that counts the number of times the AD conversion is executed. This counter counts the number of AD conversion executions by counting the end interrupt signal (pulse) output from the AD conversion unit 3 each time one AD conversion is completed.

The averaging processing unit 5 divides the total value of the digital values output from the data storage unit 4 by the preset average number of AD conversions given by the cycle control unit 6, and thereby the average value of the digital values. Is calculated. The averaging processing unit 5 outputs one digital value obtained by the averaging processing to the sampling cycle by setting a predetermined period in which the AD conversion unit 3 performs the AD conversion processing a plurality of times as a sampling cycle.

Subsequently, the AD conversion process by the AD conversion device 10 configured as described above will be described.

FIG. 2 is a flowchart showing a processing procedure of AD conversion by the AD conversion device 10. Here, an example (AD conversion method) of adding a sawtooth wave as a dither signal to an analog input signal will be described.

As shown in FIG. 2, first, the cycle control unit 6 initially sets various values (step S1). In the initial setting, the cycle control unit 6 sets the average number of times Nave, the count value (counter output value) Q, the total value S, the dither signal voltage V, and the initial values of the dither amplitude Ad in a register or the like. The initial value of the average number of times Nave is, for example, 1024. The initial values of the count value Q and the total value S are 0. If the dither amplitude Ad is, for example, a voltage corresponding to 12 LSB, the initial value of the dither signal voltage V is 0 LSB so that the dither amplitude Ad changes in the range of 0 LSB to 12 LSB. The initial value of the dither signal voltage V may be -6LSB so that the dither amplitude Ad changes in the range of −6LSB to 6LSB.

Here, the average number of times Nave is a divisor used in the averaging (division) performed by the averaging processing unit 5, and is the number of times of the AD conversion processing performed by the AD conversion unit 3. The count value Q is the count output value of the counter. The total value S is a value obtained each time the digital value is added by the data storage unit 4. The dither signal voltage V is a voltage value output from the dither signal generation unit 1. The dither amplitude Ad is the amplitude of the dither signal.

After the initial setting, the cycle control unit 6 updates the count value Q by adding 1 to the count value Q of the counter (step S2).

Next, the adder 2 adds the dither signal voltage V output from the dither signal generation unit 1 to the voltage of the input signal (input signal voltage) (step S3). The AD conversion unit 3 executes an AD conversion process on the input signal voltage to which the dither signal voltage V is added (step S4, AD conversion step). The digital value obtained as a result of the AD conversion process is stored in the data storage unit 4. Further, the AD conversion unit 3 outputs an end interrupt signal when the AD conversion process is completed.

When the AD conversion process is executed once, the cycle control unit 6 determines whether or not the current count value Q has reached the average number of times Nave (step S5). In step S5, when the cycle control unit 6 determines that the current count value Q has not reached the average number of times Nave (NO), it updates the variable (step S6) and returns the process to step S2.

In step S6, the digital value stored in the data storage unit 4, that is, the total value S is the initial value, and the digital value obtained by the AD conversion process this time (measured value Sn this time) is added. Further, the dither signal generation unit 1 receives a notification of variable update from the cycle control unit 6 and adds a value obtained by dividing the dither amplitude Ad by the average number of times Nave to the dither signal voltage V (dither signal generation step).

In step S5, when the periodic control unit 6 determines that the current count value Q has reached the average number of times Nave (YES), the cycle control unit 6 gives a reset signal to the data storage unit 4. As a result, the averaging processing unit 5 calculates the averaging value M by dividing the total value S output from the data accumulating unit 4 by the average number of times Nave (step S7, averaging processing step).

Then, the cycle control unit 6 determines whether or not the end condition is satisfied (step S8). When the cycle control unit 6 determines that the end condition is satisfied (YES), the cycle control unit 6 ends the process. The end conditions include the fact that the specified processing time (predetermined time) has been reached since the processing was started, and that the user has issued an end command. On the other hand, when the periodic control unit 6 determines that the end condition is not satisfied (NO), the variable is reset (step S9), and the process returns to step S2.

In step S9, the cycle control unit 6 resets the total value S, the count value Q, and the dither signal voltage V of the data storage unit 4. Along with this reset, the cycle control unit 6 outputs a reset signal for resetting the dither signal voltage V and the total value S to the dither signal generation unit 1 and the data storage unit 4, respectively.

As described above, a voltage that fluctuates within a predetermined amplitude range of the dither signal is added to the voltage value of the analog input signal for each of the plurality of AD conversion processes performed by the AD conversion unit 3. Such an input signal is AD-converted to a digital value, further added and averaged, so that discretization error is suppressed and high resolution is realized.

Here, the relationship between the waveform of the dither signal and the number of AD conversion processes will be described.

FIG. 3 is a diagram showing an example of a waveform of a dither signal used in the AD conversion device 10 and a relationship between a frequency distribution of signal levels and AD conversion accuracy.

As shown in FIG. 3, the dither signal has known waveforms such as a triangular wave, a sawtooth wave, a sine wave, and random noise. Triangle waves and sawtooth waves are preferable because the frequency of signal levels is uniformly distributed and the accuracy of AD conversion is good. The sine wave is slightly biased so that the frequency of the signal level is higher on the low side and the high side than on the central side, which is a usable level for the accuracy of AD conversion. The frequency of the signal level of the random noise varies, and the accuracy of the AD conversion is a usable level.

Normally, when an AD converter having a resolution of 10 bits obtains a digital output equivalent to a resolution of 16 bits by adding the dither signal voltage to the input signal voltage and then oversampling, the dither signal is a triangular wave or a sawtooth wave. If so, the number of oversamplings may be 2 ⁿ (n = 16-10 = 6). On the other hand, in the same case, if the dither signal is random noise, about 4 ⁿ (n = 6) times (2 ⁿ times the triangular wave) is required.

Subsequently, the relationship between the noise amplitude (dither signal amplitude) and the maximum error of the AD conversion will be described with reference to FIG. FIG. 4 is a diagram showing the relationship between the amplitude of noise (dither signal) generated by the AD conversion device 10 and the maximum error after AD conversion.

The figure shown on the right side of FIG. 4 is an enlarged view of a part of the figure shown on the left side. The horizontal axis of FIG. 4 shows the noise amplitude [LSB], which is the LSB at the original resolution of the AD conversion unit 3 before oversampling (for example, in the case of 10 bits, the reference voltage / 2 ¹⁰ = 1 LSB). The vertical axis shows the maximum error [LSB] of the AD conversion, and is the LSB when calculated with the resolution after oversampling (for example, in the case of 16 bits, the reference voltage / 2 ¹⁶ = 1 LSB). The relationship shown in FIG. 4 is based on the results obtained by repeating oversampling 1024 times.

As shown in FIG. 4, in the range where the noise amplitude is 6 LSB or more and 260 LSB or less, the maximum error of AD conversion is 2 LSB or less. Further, in the range where the noise amplitude is 12 LSB or more and 120 LSB or less, the maximum error of AD conversion is 1 LSB or less.

On the other hand, when the noise amplitude is 2LSB (± 1LSB), the maximum error of AD conversion becomes almost 0, but if the noise amplitude deviates from 2LSB even by a small amount, the maximum error of AD conversion sharply increases. Therefore, as described in "Problems to be Solved by the Invention", a circuit or environment in which a very small voltage equivalent to 2LSB is accurately added to the input signal without error each time is provided at a practical cost. It is difficult to realize with.

The range (reference voltage) of the input voltage that the AD conversion unit 3 can perform AD conversion is determined. Therefore, when a dither signal is added to the input signal, the voltage width of the input signal that can be AD-converted becomes narrow. Therefore, when the maximum error of AD conversion is 2LSB, it is preferable that the amplitude of the dither signal is not close to the upper limit of 260LSB but smaller. However, for example, when the sensor 30 is a thermocouple and the change width of the temperature of the measurement target is relatively small, the range of the input voltage required for the measurement is also relatively small. Therefore, in this case, the range in which the digital value can be obtained according to the required resolution becomes small, so even if a dither signal having an amplitude corresponding to the upper limit of 260 LSB is added, AD conversion can be performed without any problem. is there.

In the AD conversion device 10 of the present embodiment, the resolution can be improved by calculating the average of a plurality of digital values obtained as a result of repeating the AD conversion process by the AD conversion unit 3 a plurality of times. Specifically, if the resolution of the AD conversion unit 3 is 10 bits, by performing the AD conversion processing 1024 ^{(= 2 10)} times, it is possible to obtain a digital value corresponding to the resolution of 16 bits.

The number of AD conversion processes is appropriately set according to how much the resolution is improved, and may be 64 (= ²⁶ ) times or the like.

Further, by setting the noise amplitude in the above range, the maximum error of AD conversion can be suppressed to a practical value. Specifically, since the dither signal has a voltage amplitude corresponding to 6 LSB or more and 260 LSB or less, the maximum error of AD conversion can be suppressed to 2 LSB or less. Further, since the dither signal has a voltage amplitude corresponding to 12 LSB or more and 120 LSB or less, the maximum error of AD conversion can be suppressed to 1 LSB or less.

Therefore, even if the amplitude of the dither signal varies or has an error, the effect on the resolution is small. Therefore, stable AD conversion performance can be obtained at a practical cost.

[Example of realization by software]
The control block (particularly the periodic control unit 6) of the signal processing device 100 may be realized by a logic circuit (hardware) formed in an integrated circuit (IC chip) or the like, or may be realized by software.

In the latter case, the signal processing device 100 is a CPU (Central Processing Unit) that executes instructions of a control program that is software that realizes the function, and a ROM (Read Only) in which the above program and various data are readablely recorded by the CPU. It is equipped with a Memory) or a storage device (referred to as a "recording medium"), a RAM (Random Access Memory) for developing the above program, and the like. Then, when the CPU reads the program from the recording medium and executes it, the object of the present invention is achieved.

As the recording medium, a "non-temporary tangible medium", for example, a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. Further, the program may be supplied to the computer via an arbitrary transmission medium (communication network, broadcast wave, etc.) capable of transmitting the program.

The present invention can also be realized in the form of a data signal embedded in a carrier wave, in which the above program is embodied by electronic transmission.

[Additional notes]
The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention.

1 dither signal generation unit 3 AD conversion unit 5 averaging processing unit 10 AD conversion device 20 signal output unit 100 signal processing device

Claims (6)

A dither signal generator that generates a dither signal to be added to the analog input signal,
An AD conversion unit that performs processing to convert the analog input signal to which the dither signal is added into a digital value, and
An average value of the digital values obtained by performing the conversion process by the AD conversion unit a plurality of times within a predetermined period is calculated and output as a digital signal after AD conversion having the predetermined period as a sampling cycle. With a processing unit,
The dither signal is an AD conversion device whose value fluctuates within an amplitude range corresponding to a value set in a range of 6 LSB or more and 260 LSB or less in the predetermined period. The AD conversion device according to claim 1, wherein the dither signal fluctuates in a range of amplitude corresponding to a value set in a range of 12 LSB or more and 120 LSB or less in the predetermined period. The AD conversion device according to claim 1 or 2, wherein the value of the dither signal fluctuates as a triangular wave or a sawtooth wave in the predetermined period. The AD conversion device according to any one of claims 1 to 3.
A signal processing device including a signal output unit that outputs a digital signal output from the AD conversion device. A dither signal generation process that generates a dither signal to be added to an analog input signal,
An AD conversion step of performing a process of converting the analog input signal to which the dither signal is added into a digital value, and
An average value of the digital values obtained by performing the conversion process in the AD conversion step a plurality of times within a predetermined period is calculated and output as a digital signal after AD conversion having the predetermined period as a sampling cycle. Including the processing process,
An AD conversion method in which the value of the dither signal fluctuates within an amplitude range corresponding to a value set in a range of 6 LSB or more and 260 LSB or less in the predetermined period. The AD conversion method according to claim 5, wherein the dither signal fluctuates in a range of amplitude corresponding to a value set in a range of 12 LSB or more and 120 LSB or less in the predetermined period.

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