DE3825884A1 - Method for increasing the resolution of an A/D converter - Google Patents

Abstract

A method for increasing the resolution of an A/D converter is described which converts an analog input signal value into a corresponding digital output signal value. When a conversion process is carried out, a comparison between the analog value to be converted and an analog signal corresponding to a predetermined digital signal and passing through a predetermined range of values in the course of a conversion cycle is carried out in the converter. When the method is used, a number of conversion cycles are carried out and the digital values obtained in each case are stored. In addition, the frequencies of occurrence of the individual digital values are stored. The curve of the statistical distribution of the stored digital values is calculated using the stored frequencies. The digital value corresponding to the peak of the calculated curve is taken as the digital output value to be generated.

Description

The invention relates to a method for increasing the Resolution of an A / D converter that has an analog input i signal value into a corresponding digital output signal value converts, the digital output signal value by comparison of the analog input signal value to be converted with an im Course of an implementation cycle a predetermined value range continuous, correspond to a predetermined digital signal the analog signal is determined.

A / D converters usually contain one comparator, the two compares analog signals. The first signal is the analog signal to be converted. The second signal is a signal that is in a known relationship with a digita len signal, so that each of its individual values the associated digital value is known. If in the course of nes implementation cycle the comparator the equality of it too led signals is used as a digital output digital value taken that corresponds to the value of the  corresponds to the second analog signal that was detected there was agreement by the comparator.

A / D converters of this type work with a certain resolution ability, which is due to the fact that the digital Output signal consists of individual digital values, between which is a predetermined distance, the small step size is determined by which the analog to be implemented GE signal must change so that switching from a digital Initial value for the immediately following digital off current value takes place. For example, if it is assumed that the analog signal to be converted is a voltage, then can, for example, with a certain resolution a change in voltage of 10 mV a changeover from a digital output value to the next digital output evoke worth. On the other hand, the converter has a larger resolution capacity, then switching from a digital Initial value for the next one, for example, after one Change of the analog voltage by 1 mV.

A / D converters of the type described are frequently used to convert measured values which are in the form of analog signals into digital values which can then be further processed with the aid of digital circuits. To achieve high accuracy, a high resolution of the converter is often desirable. Achieving a higher resolution is especially when a certain large resolution already exists, associated with a relatively large circuit complexity, which drives up the manufacturing costs of the converter. Since A / D converters are often produced in the form of integrated circuits, the increased circuit complexity often leads to space problems on the semiconductor chip, so that if a greater resolution is required under all circumstances, a more complex technology may be used in the production must to meet the desired requirements.

The invention has for its object a method of to create the type described above, through its application the resolution of an A / D converter can be increased, without the circuitry complexity being increased.

This object is achieved in that the Analog input signal value to be converted in a given Number of successive implementation cycles with the compare the specified digital value with the corresponding analog signal Chen is that in each implementation cycle with established Agreement of the compared sizes of the present predefined digital value and the frequency of occurrence of the digital value is stored using the stored frequencies the curve of statistical ver division of the stored digital values is calculated and that the Digi corresponding to the maximum of the calculated curve talwert as the digital output signal value to be generated ge is taken.

The application of the method according to the invention lies in the observ attention that the to be compared in the implementation Signals are not exactly constant, but their relative position change to each other. These changes include one the noise superimposed on the signals. Thereby is used in several implementation cycles not always get the same result, but it can be a statistical distribution of the result obtained watch them. By evaluating this distribution under Be taking into account the laws of statistics can be an implementation result that is more accurate than the result, purely arithmetically due to the circuitry construction of the converter can be reached. By applying the he method according to the invention, the A / D converter behaves in such a way as if he has a resolution greater than that that can actually be expected due to its structure.  

An advantageous development of the method consists in that at least one of the two at each implementation cycle comparing signals a noise signal is superimposed. These Further training is advantageous if the ver Similar analog signal values are very constant, so that no statistics in the case of repeated implementation cycles distribution of the results. By overlaying egg nes statistically evaluable signal, especially one Noise signal, the statistical distribution is brought about, the prerequisite for the application of the Ver driving is.

The invention will now be described by way of example with reference to the drawing explained. Show it:

Fig. 1 is a schematic representation of a principle embodiment of an A / D converter for the appli cation of the inventive method and

FIG. 2a) and 2b) are diagrams for explaining the inventive method SEN.

The A / D converter 10 shown in FIG. 1 of the drawing is well suited to make the method for increasing the resolving power, which will subsequently be explained in more detail, understandable. The A / D converter 10 contains as a main component a Kompa rator 12 with two inputs 14 , 16 and an output 18th It also contains a counter 20 and a D / A converter 22 . The comparator 12 receives at its input 14 an analog signal to be converted into a digital signal, which is applied to the converter input 24 . To control the conversion cycles, a counter is fed to the counter 20 at a further converter input 26 , which causes the counter to run through its entire counting range once in each conversion cycle. The digital signals emitted by the counter, representing the respective counter readings, are converted by the D / A converter 22 into an analog signal, which is fed to the input 16 of the comparator 12 . The output signal of the D / A converter is an analog staircase signal, of which each stage represents a certain digital value. The height of a stage corresponds to the smallest value to be resolved of the analog signal to be converted.

The A / D converter 10 can, for example, be designed such that the D / A converter 22 supplies the input 16 of the comparator 12 with a voltage which rises under the control of the counter 20 in steps of 1 mV. The voltage can start, for example, with the value 10 mV and rise up to 2 V. When implemented, an analog signal in the form of a voltage of 725 mV is present at input 14, for example. As soon as the conversion cycle is triggered by applying a control signal to the input 26 , the counter 20 begins to continuously increase its counter reading from zero. The output signals of the counter are converted by the D / A converter 22 into an analog voltage, the value of which increases each time the state of the counter 20 increases by 1 mV. As long as the voltages at the inputs 14 and 16 of the comparator 12 are different, the output 18 of the comparator emits a signal with the value "0" for example. As soon as the analog voltage at input 16 reaches the value of the voltage at input 14 , the signal at the comparator output switches to the value "1". This switching is used by means of a control circuit, not shown, to stop the incrementing of the counter 20 ; in addition, the counter 20 reached is recorded as the value which corresponds to the voltage value at input 14 in digital form.

If several conversion cycles are carried out with the same analog input voltage, theoretically the same state of the counter 20 should always result, in which the comparator shows the equality of the compared signals. In practice, however, the signals applied to the comparator 12 are not completely constant, which is partly due to the noise level usually present in analog signals. When carrying out several successive implementation cycles, different results are obtained which are used when applying the method to be described.

If the same result is always achieved with several conversion cycles, which means that the voltage supplied to the comparator 12 at the input 14 is very constant and the voltage supplied to the input 16 is completely noise-free, then with a converter 10 of the type described exactly the resolution can be assets can be achieved, which is determined by the smallest possible counting step of the counter 20 . As was explained above, the counter 20 can be constructed in such a way that the input 16 is supplied with a step-like voltage, each with values increasing by 1 mV. The smallest voltage value to be resolved is therefore 1 mV, so that, for example, the result obtained is that the applied analog voltage in digital representation has the value 750 mV or the value 751 mV or the value 752 mV etc. However, it is not possible to determine that the voltage has the value 751.5 mV, for example, since this would require a higher resolution. With the help of the method to be described, this large resolution can be achieved.

When carrying out the method to be described, several successive implementation cycles are carried out, which proceed as described above. The result of each conversion cycle is a digital output signal value that speaks to the analog input signal value supplied to the converter. When the multiple conversion cycles are carried out, different output signal values are obtained on account of the noise contained in the signals and are stored for later processing. However, not only are the various values obtained saved, but it is also recorded how often these individual values have occurred over the course of the several conversion cycles. Thus, the plurality of conversion cycles, can be specified by performing that the voltage value U _{d 1} (ml) times the voltage value U _{d 2} (2m) times the voltage value U _{d 3} (3m) times the voltage value U _{d 4} (m4) times, etc.

Based on this stored information, the curve of the statistical distribution of the measured values obtained can be calculated, which can be represented in a distribution curve according to FIG. 2b). In Fig. 2a) the step-like rising analog ge voltage is shown, which is fed to the comparator as a comparison signal. Each staircase corresponds to this analog voltage with a certain digital value.

As can be seen from FIG. 2b), the curve of the statistical distribution of the measured values obtained has a maximum at the voltage value U ₀ , which lies between the voltage value U _{d 2} and the voltage value U _{d 3} . If it is assumed that the diagrams of FIG. 2 are approximately to scale, then it can be said that the probable value of the analog signal to be implemented is U _{d 2} + 0.25 × Δ U if Δ U is the interval between two corresponds to successive voltage values, for example has the value U _{d 3} - U _{d 2} .

The desired improvement in resolution is influenced by several parameters. In addition to the desired improvement in resolution, a factor known in statistics, namely the confidence number γ , must be taken into account, which is a measure of the reliability of the results obtained. Using the laws of statistics, for a required confidence number γ and for a specific ratio of the voltage Δ U to the width σ of the distribution curve, the number of conversion cycles, i.e. measured values, to be calculated for the calculation of the distribution curve can be calculated by to achieve a certain improvement in resolution. The significance of the confidence number for this assessment comes from the book "Statistical Methods and Their Applications" by Dr. Erwin Kreyszig, 7th edition, 1979, in particular pages 182, 183 and 273.

In practice, it was possible to obtain a result that corresponded to the result of a 14-bit A / D converter by using the described method using the 12-bit A / D converter. While it was only possible with the 12-bit A / D converter to make the statement that, for example, the voltage to be converted had the value U _{d 1} or U _{d 2} or U _{d 3} etc., the evaluation using the described method are refined so that the measured value could be specified in steps of Δ U / 4.

It should be noted that the construction of the A / D-Um is only one of many possible designs, at which the described method can be used. Also the counter values given are only examples that are for the better should contribute to their understanding.

Prerequisite for the applicability of the procedure described It is rens that when implementing several implementers Results different measurement values can be obtained. This is in practice, it is usually always the case, as described above Rauschan has already mentioned the signals to be compared Have parts so that the signals to be compared relative fluctuate with each other and consequently un in comparison result in different values with statistical distribution. However, if there are not enough different measured values ben, so that a statistical evaluation is not too reliable results, at least one of them can be compared signals are superimposed on a noise signal because then in any case the desired different measured values the implementation cycles carried out.

Claims (3)

1. A method for increasing the resolution of an A / D converter which converts an analog input signal value into a corresponding digital output signal value, the digital output signal value being compared by comparing the analog input signal value to be converted with a cycle through a predetermined value range in the course of a conversion cycle Given the corresponding digital signal, the corresponding analog signal is determined, characterized in that the analog input signal value to be converted is compared in a predetermined number of successive conversion cycles with the analog signal corresponding to the predetermined digi tal value, that the predetermined digital value present is present in each conversion cycle if the compared quantities are found to be the same and the frequency of occurrence of the digital value is stored from that using the stored frequencies, the curve of the statistical distribution of the stored digital values is calculated and that the digital value corresponding to the maximum of the calculated curve is taken as the digital output signal value to be generated. 2. The method according to claim 1, characterized in that ver at least one of the two in each implementation cycle same signals over a statistically evaluable signal is stored. 3. The method according to claim 2, characterized in that the statistically evaluable signal is a noise signal.