This application claims the priority benefit of Italian patent application serial number MI2012A001116, filed Jun. 26, 2012, which is hereby incorporated by reference to the maximum extent allowable by law.
1. Technical Field
This disclosure relates to analog-to-digital converters and more particularly to an integrated analog-to-digital converter having an improved accuracy and a reduced silicon area occupation, particularly suited for PSI5 and WSS (Wheel Speed Sensor) systems, and a related interface for PSI5 and WSS systems.
2. Discussion of the Related Art
Analog-to-digital converters are electronic devices even more frequently used in the automotive field for realizing interfaces of analog sensors installed in vehicles to a central control unit. In particular, the so-called PSI5 (Peripheral Sensor Interface) is even more used, for example, in combination with airbag sensors, and are characterized by limited costs, high speed and reliability of the data transfer and low overhead.
A typical example of a control system made of sensors connected to an electronic control unit (ECU) having a PSI5 interface is depicted in
Nowadays, the most effective solution for processing a received analog signal consists substantially in converting the analog signal into a digital signal and in carrying out a demodulation of the digital data such to obtain a bit sequence adapted to be processed directly by a controller or a microprocessor for implementing a desired control action.
Downstream from the analog-to-digital converter, at least an anti-aliasing filter is typically provided for canceling conversion noise, such to prevent it from disturbing the demodulated noise. In PSI5 or WSS (Wheel Speed Sensor) systems, it is desirable to carry out fast analog-to-digital conversions and the successive low-pass filtering and to make these operations relatively robust against noise.
An analog-to-digital conversion loop has a feedback line including a digital-to-analog converter that provides an analog replica of the generated digital signal. Because of design constraints of the above mentioned systems, it is particularly important to realize this feedback loop such to obtain an output that goes quickly to the desired level corresponding to the time-varying analog input signal.
U.S. Pat. No. 6,229,469 shows an analog-to-digital conversion loop, shown in
A limitation of this analog-to-digital conversion loop consists in that it needs a sample and hold circuit in order to function correctly in presence of large variations of the input signal. Moreover, the used flash analog-to-digital converter is linear. Therefore, its architecture is as shown in
The sample and hold circuit is needed in this architecture because it holds the analog error signal for the time necessary to allow the propagation thereof throughout the comparators, the encoder and the output buffer. If the sample and hold circuit were removed, then, in presence of a time varying input signal, the output buffer would upload a digital datum while the input is changing, thus causing errors that may be relevant.
Another known solution is depicted in
U.S. Pat. No. 6,100,834 discloses an analog-to-digital conversion loop, shown in
A drawback of this analog-to-digital conversion loop consists in the presence of the high-pass filter, that is relatively complex to realize. Moreover, the flash analog-to-digital converter should be particularly fast to generate an accurate digital replica of the high-pass signal S1, otherwise the depicted conversion loop would not function correctly because it does not have the sample and hold circuit, necessary for keeping constant the input of the converter for the time necessary to carry out the conversion.
a and 8b depict known current sensing architectures of PSI5 and WSS sensors, that have a threshold-based discrimination system. They substantially compare a current ISat/100, that represents an analog quantity to be converted, with a threshold current determined by a logic circuit able to define the range to which the current belongs.
The architecture of
Even if the depicted circuits have a relatively fast transient response, they occupy a relevant silicon area and further they do not have a good noise rejection.
It would be desirable to have a sufficiently fast analog-to-digital conversion loop that may be embedded in PSI5 or WSS systems, that occupies a reduced silicon area and that has a good noise rejection.
Studies carried out by the Applicant aimed to find a solution that satisfies all the above requirements, apparently incompatible, led to the realization of an innovative analog-to-digital conversion loop wherein the analog-to-digital converter has a nonlinear input-output conversion characteristic with a larger quantization step the more the input to be converted differs from a null value, such to analog-to-digital convert in a refined manner during quasi steady-state conditions, when the analog error signal is practically null, and in a relatively coarse manner during transient conditions.
The applicant has found that such an embodiment of an analog-to-digital conversion loop is particularly suited for interfaces of PSI5 or WSS systems because they are characterized by substantially square wave input signals to be converted. In these interfaces it is thus required to make the digital output tend quickly to the analog input signal to be converted when the latter switches, though the accuracy of the conversion in transient conditions, that is when the signal switches from a level to another, is not a strict requirement.
Thus, an embodiment provides an analog-to-digital conversion loop comprising:
According to an embodiment, the analog-to-digital converter has a logarithmic characteristic and the digital integrator is a counter.
The herein proposed conversion loop may be embedded in PSI5 interfaces or in interfaces adapted to be connected to WSS sensors.
The claims as filed are integral part of this description and are herein incorporated by reference.
a and 8b show exemplary diagrams of analog-to-digital conversion loops for PSI5 and WSS systems, respectively.
a and 11b show architectures of analog-to-digital voltage and current converters adapted to be used in the analog-to-digital conversion loop of this disclosure.
a, 12b and 12c show Simulink™ schemes of the analog-to-digital conversion loop according to this disclosure, shown in
a and 14b show time graphs that illustrate the transient functioning of the conversion loop of this disclosure.
A basic diagram of the herein proposed analog-to-digital conversion loop is shown in
A difference between the novel analog-to-digital conversion loop and the prior loop shown in
The input of the analog-to-digital converter is substantially an error signal, that in steady-state conditions is null because of the integrator in the feedback loop, thus it is sufficient to perform an accurate conversion only in correspondence of the null value of the error signal in order to have an analog-to-digital conversion loop adapted to be used in all applications, such as the PSI5 and WSS systems, in which accuracy in transient conditions is not a strict requirement.
With the same number of comparators of the analog-to-digital converter, a better accuracy in quasi-steady state conditions is obtained with a converter with a nonlinear conversion characteristic than with a converter with a linear conversion characteristic. Moreover, using a nonlinear converter, it is not necessary to use a sample and hold circuit, when the conversion loop is to be embedded in a PSI5 or WSS system. Indeed, without this sample and hold circuit there is a relevant error during transient conditions, though in PSI5 or WSS systems this transient error has no or little influence on the functioning of the system in which the loop is embedded, because in quasi steady-state conditions the output is an accurate digital replica of the analog input.
Tests carried out by the applicant have shown that analog-to-digital converters with a logarithmic input-output characteristic are particularly suited for the application. For this reason, in the ensuing description reference will be made to this particular embodiment, though what will be stated holds mutatis mutandis also for nonlinear converters of other types.
According to an embodiment, that is particularly easy to implement, the integrator is substantially a counter or a digital circuit configured to carry out the same function.
An exemplary block diagram of the novel analog-to-digital conversion loop is shown in
Detailed diagrams of voltage and current analog-to-digital converters with a logarithmic characteristic are shown in
Simulink™ circuits used for simulating the functioning of the novel analog-to-digital conversion loop of
In the embodiment shown in the just described figures, the updating of the digital output value is carried out by means of a buffer and a feedback loop, but a similar result may be obtained by means of an up/down counter whose counting is updated in function of the value DIFF.
a and 14b are graphs of the square-wave signal X(t) to be converted not corrupted by noise, of the analog replica Y(t) of the digital output signal and a time graph of the error E(t) during transients conditions. The herein proposed conversion loop generates a digital output signal affected by a relatively great error in correspondence of the switching of the input signal, though this error tends rapidly to the null value.
The novel analog-to-digital conversion loop is thus capable of providing a digital output signal corresponding to a low-pass replica of the analog input signal, has shorter extinction times in transient conditions, as well as a refined accuracy in quasi-stationary functioning conditions. Moreover, with the same input dynamics, the herein proposed conversion loop may be implemented on silicon with a relevantly smaller area occupation than that of known conversion loops.
The herein proposed analog-to-digital conversion loop may be conveniently embedded in PSI5 interfaces of electronic control units for automotive applications and more in general in any communication channel with characteristics substantially similar to those of PSI5 or WSS systems.
Having thus described at least one illustrative embodiment of the invention, various alterations, modifications, and improvements will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be within the spirit and scope of the invention. Accordingly, the foregoing description is by way of example only and is not intended as limiting. The invention is limited only as defined in the following claims and the equivalents thereto.
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