DE19825560A1 - Analog-digital converter for heating control - Google Patents

Abstract

A current source (2) is connected via a channel driver (4) to a channel (30) when a passive device is connected to the channel, to produce a passive analog measurement signal. The current source is deactivated when an active device, providing an active analog measurement signal, is connected to the channel. The passive or active analog measurement signal is applied via the same channel, and the channel driver, to an evaluation unit (8), to determine a digital measurement value.

Description

The invention relates to an analog-digital converter to which active and passive devices can be connected. Such analog-digital converters are required, for example, in the Heating control technology. In heating technology, on the one hand passive temperature sensor used, such as PT 100 sensor, PT 1000 sensors, PTC and NTC resistors and the like, which in essential temperature-dependent resistors are; other on the other hand, actuators and active signal generators, e.g. B. with an output voltage between 0 and 10 volts to ground, in front.

The conventional analog-digital converter can only the Sig evaluate signals of the active signal generators, d. H. analog chip voltage or current signals. For measuring a resistance  a passive sensor is also an external power source and a control circuit necessary to the passive sensor to feed with a current and so one of the analog-digital To generate transducers detectable voltage signal.

There are also hybrid analog-digital in the prior art Converter for active and passive devices as well as analogue di gital converter, in which the functions described above in Form of printed circuits are realized discretely. Such hybrid analog-to-digital converter and the printed circuits have the disadvantage that when resistors and signals from active signal generators are processed in the same circuit should, the channels for the resistors and the signal generator in must be determined in advance.

It is not possible with the circuits of the prior art Lich, a measuring current to one over the same channel passive sensor to output an analog measurement signal testify, and this measurement signal or the signal of an active Read signal generator. The Ana’s multiple input channels Log-to-digital converters are therefore used in advance for connection only active or only passive devices set up and to the expected measuring ranges, such as the size of the voltage range rich or resistance range, adapted. In addition, an external power source is provided to the passive device to eat.

In heating control technology, e.g. B. become analog-to-digital converters with predefined input channels for active signal generators (0 to 10 volts) and for different temperature sensor elements, like PT 100, PT 500 etc., PTC or NTC resistors, Ni 100- Sensor etc., fixed.

It is an object of the present invention to provide an analog To provide digital converters, particularly in the field the heating control technology can be used and for the An  passive sensor and active signal generator without restrictions suitable for a certain sensor type is.

This task is accomplished with an analog-to-digital converter Features of claim 1 solved.

The invention provides an analog-to-digital converter with little at least one channel for connecting both active and pas sive devices in front of a switchable power source, a Includes evaluation unit and a channel control unit. Before preferably, the analog-to-digital converter according to the invention has meh Other input / output channels. If the resistance of a pas sive device to be detected, this can be to a be any channel. The channel control unit then connects the power source to the corresponding channel, to conduct a current through the passive device so that a voltage drops across this, which is referred to as a "passive" ana log measurement signal is used. This passive analog measurement signal can to the off via the same channel and the channel control unit unit of value to create a digital measured value conduct. If the signal from an active device, e.g. B. one Signal generator with a voltage between 0 and 10 volts, detected the active device can be connected to another or be connected to the same channel that becomes the power source disabled, and the signal from the active device is as an "active" analog measurement signal via the channel control led to the evaluation unit.

The analog-digital converter according to the invention is preferred in the form of an integrated circuit as ASIC (application spec specific integrated circuit).

The channel drive unit preferably comprises a first and a second input multiplexer connected between the stream source and the input / output channels or between the inputs  gangs / output channels and the evaluation unit are switched, so that a measuring current as required via one and the same channel output and a measurement signal from an active or a pas active device can be read.

The current source is preferably adjustable to one to the connected passive device adapted measuring current he to be able to testify. In a heating control system, e.g. B. from depending on the connected temperature sensor types different measuring currents are output.

In a preferred embodiment, the evaluation comprises one is a measuring amplifier with an adjustable gain factor, which can be designed as a push-pull amplifier, and one Voltage-frequency converter and a pulse counter.

Furthermore, an external or internal, i.e. H. integrated Control device for setting at least one of the follow the parameters can be provided: measuring current, measuring time, measuring amplifier kung, channel.

Finally, to connect the active or the pas active devices a passive and a passive mass will be seen as in the following description of the figures is explained in more detail.

The analog-digital converter according to the invention is used, for example, in the field of heating control technology, although it is of course not restricted to this application. The way it works is basically as follows:
When measuring temperature using temperature sensors, electrical resistances must be measured. For this purpose, a defined measurement current is driven via the input multiplexer through one of the sensor resistors connected to the channels.

The common "passive" mass of the feelers is applied to a pot tial of z. B. 3 volts raised to a suitable measuring range to create. Due to the current through the sensor arises a voltage drop proportional to the resistance of the sensor, which is tapped by the input multiplexer and the measuring ver is fed more. The input multiplexer consists of a first analog multiplexer for switching the measuring current a specific channel and a second analog multiplexer to measure the voltage on the same channel. From the second The input multiplexer sends the signal to the measuring amplifier. Here is a suitable choice of the gain factor ensured that the following voltage-frequency converter is optimally controlled. The voltage-frequency converter sets the input voltage processed in this way into a proportional Frequency around. During a given by the control device benen measuring period, the frequency pulses are counted, and thus the measured variable is converted into a digital signal.

For optimal functioning of the digital-to-analog converter, there are one Range of settings required during operation, such as the Choice of the measuring current, the determination of the amplification factor of the Measuring amplifier and the choice of channel. These are from the Control device, for example a microcontroller, the Analog-digital converter communicated. The microcontroller can in an alternative embodiment also in the Analog-Di gital converter.

With the analog-to-digital converter, voltages in the load rich from z. B. 0 to 10 volts can be measured against ground. To the measuring current is switched off for this purpose. In the measuring amplifier a gain ≦ 1 is set, i. H. the signal is ge dampens and by adding a voltage into one for the Voltage-frequency converter transformed favorable range.

The invention is based on a preferred Aus management form explained with further details. In the Figu  ren shows:

Fig. 1 is a block diagram of the analog-digital converter according to the invention in the form of an ASIC; and

Fig. 2 is a block diagram of a voltage-frequency converter which is inserted in the digital-to-analog converter of Fig. 1.

The figure shows the analog-digital converter according to the invention in the form of an ASIC 1 (ASIC = Application Specific Integrated Circuit; application-specific integrated circuit). The ASIC 1 comprises a current source 2 , a channel control unit 4 and an evaluation unit 6 .

The channel control unit 4 comprises a first and a second analog multiplexer, of which only one is shown in the figure. The evaluation unit 6 comprises a measuring amplifier 8 , a voltage-frequency converter 10 and a pulse counter 12 . Furthermore, the ASIC 1 shown in the figure also has a control word decoder 14 , a time control device 16 , an interface encoder 18 , a reset control 20 and a voltage source 22 . These components of the ASIC 1 are connected to one another in the manner shown in the figure. In addition, the current source 2 is connected to a reference resistor 24 , the timing device 16 is connected to a clock crystal 26 , and the voltage-frequency converter 10 is connected to an integration capacitor 28 .

In the channel control unit 4 , the first and the second (not shown) analog multiplexer with 28 channels 30 are connected, to which passive and active devices can be connected without restriction. Of course, the number 28 is just an example. From the voltage source 22 leads to the outside designated "sensor ground" connection 32 , which is used to connect the ground connection of the passive devices. A port 34 labeled V _SSA serves as the ground for the active devices, as will be explained in more detail below. Furthermore, two connections V _DD 36 and V _SS 38 are shown in the figure, which serve as connections for the digital voltage supply of the ASIC 1 . The connections MOSI 40 , SCLK 42 , SCS 44 and MISO 46 form an interface to an external microcontroller (not shown) for controlling and specifying parameter values for the ASIC 1 , as will be described further below. An external residual line is designated 48 . A V _DDA 50 connection serves as an input for an analog supply voltage. Finally, a test line 52 is also provided.

In a preferred embodiment of the invention, the ASIC 1 is designed as an analog-digital converter for a heating control system. It is suitable for connecting the common passive temperature sensor types, as will be explained in more detail later, and for connecting active signal transmitters with a. Output voltage in the range of, for example, 0 to 10 volts. The connection of the passive sensor and the active signal transmitter to one of the 28 channels 30 is arbitrary, a separate common ground 32 and 34 being provided for the passive sensors and the active signal transmitter. An SPI interface (standard interface from Motorola Inc.) 40 to 46 is provided for connecting the microcontroller (not shown) for controlling the ASIC. This allows parameters such as measuring current, measuring time and amplification to be set individually for each channel. The measuring current can be set in the current source 12, for example, in steps of 0.5 mA in the range from 0.5 mA to 2 mA. The digital supply voltage is, for example, 5 volts, the analog supply voltage, for example, 12 volts.

In operation, one or more passive devices can be connected between one or more of the channels 30 and the passive ground 32 , and one or more active signal transmitters can be connected between one or more of the channels 30 and the active ground 34 . The analog multiplexer, which is part of the channel drive unit 4 , connects each channel 30 via a first multiplexer or transistor (not shown) to the current source 2 and via a second multiplexer or a transmission gate (not shown) to the input of the measuring amplifier 8 . The external microcontroller (not shown) can thus control and call up any channel via the SPI interface 40 to 46 . The channel is selected from the analog multiplexer by applying a voltage, for example 12 volts, to a corresponding selection input. If the selection input is at ground, the transistor and the transfer gate are high impedance and the corresponding channel is cut off.

As already mentioned, the microcontroller can also be integrated in the ASIC 1 .

In practice, the evaluation unit 6 and in particular the voltage-frequency converter 10 has a lower control limit that is greater than 0 volts. It must therefore be ensured that the passive or active analog measurement signal does not fall below this limit. A common reference potential or a "passive" mass 32 is therefore generated for the passive sensors, which is greater than the lower control limit of the components of the ASIC 1 and in particular the evaluation unit 6 . In the case of the active signal generators, which generate a voltage between 0 and 10 volts, for example, it is assumed that the falsification of the signal by overdriving the measuring amplifier 8 is in the lower range within the scope of an acceptable measurement error, the voltage of the active signal generators being sent to the drive range of the voltage-frequency converter 10 can be adapted, which is described below. In realizing the present invention, it has been shown that the value of the summation point of the voltage-frequency converter 10 (see FIG. 2) is a favorable reference potential for the passive ground 32 .

This results in a common "floating" mass for all passive devices or sensors, which is generated by the voltage source 22 . This measure also serves as overload and short-circuit protection.

If the analog-to-digital converter according to the invention is used in a heating control system, it must be able to support sensor types which have areas of resistance which differ greatly from one another. In order to nevertheless achieve a good temperature resolution of, for example, 0.05 K, the voltage-frequency converter 10 must be optimally controlled, ie the voltage range of the signal to be converted should, with its upper and lower limits, be as close as possible to the modulation limits of the voltage Frequency converter. Linear amplification, which can be set in stages by the microcontroller via the SPI interface 40 to 46, is usually sufficient for this. The measuring amplifier 8 is formed in an exemplary embodiment as an electrometer amplifier, in which the change in the gain factor takes place by setting various negative feedbacks. For this purpose, a voltage divider (not shown) is placed between the output of the measuring amplifier and ground, which can consist of a series connection of resistors. Similar to a potentiometer, this voltage divider is tapped at various points by means of a transmission gate. The partial voltages are fed to the inverting input of the measuring amplifier 8 . Since practically no current flows into this input, the transmission gates are operated virtually without current, and there is no voltage drop that could distort the measurement.

For the measuring range of z. B. 0 to 10 volts of the active signal transmitter is arranged in a preferred embodiment of the invention, a resistance network (not shown) at the output of the measuring amplifier 8 , which according to the relationship U _output = (12 volts + U _input ) / 3 the signal of active signal generator (0 to 10 volts) in a usable for the voltage-frequency converter 10 range from 4 to 7.33 volts. With the help of second transmission gates (not shown) in the evaluation unit 6 can be switched between the "active" and the "passive" mode, the measuring amplifier 8 is always switched to a gain factor ≦ 1 when the 0 to 10 volt mode is switched on.

The voltage-frequency converter 19 works in an embodiment of the invention according to the charge balancing method or charge equalization method and generates an output frequency proportional to its input voltage, which is counted during a defined measuring time by the pulse counter 12 to derive the corresponding digital value.

Fig. 2 shows a block diagram of a voltage-frequency converter, which can be used in the evaluation unit 6 .

The voltage-frequency converter of FIG. 2 comprises an input resistor 54 , an integrator 56 with an integration resistor 58 and an integration voltage source 60 , a comparator 62 with a threshold voltage source 64 , an AND gate 66 , a D flip-flop 68 with a clock input 70 and a switch 72 with a resistor 74 , which are connected in the manner shown in FIG. 2 with an input ON and an output OFF of the voltage-frequency converter. When a voltage is applied to the input of the voltage-frequency converter, a current flows through the input resistor 54 , which discharges the integration capacitor 58 in the position of the switch 72 shown until the output voltage of the integrator 56 is equal to the threshold voltage 64 of the comparator 62 is. Then the switch 72 is closed during a clock period in order to supply a precisely defined amount of charge to the capacitor 58 and to charge it. (The integration capacitor 58 corresponds to the capacitor 28 in FIG. 1.) The switch 72 is then brought back into the position shown in FIG. 2, and the capacitor is discharged again until the integrator output is again at the threshold voltage 64 of the comparator 62 is. Then the cycle starts again. With the described method of charge balancing voltage-to-frequency converter produces at the output an output frequency which is adjacent to the input voltage only from pending from the known frequency f of the _CLOCK and also known Bezugsspanung the voltage source 60th This output frequency is converted into a digital signal via the pulse counter 12 and the SPI encoder 18 and passed on to the microcontroller via the SPI bus 46 .

Constant currents are required at various points within the ASIC 1 during operation. In particular when measuring passive sensors, a suitable measuring current must be made available. For this purpose, a reference current of 100 µA is generated, for example. In one embodiment of the invention 2, the power source and an operational amplifier (not shown) by a switched transistor, which is maintained with the voltage at the external reference resistor 24 to a reference voltage value constants kon. The current thus obtained through the resistor and the transistor is passed through further transistors (not shown) in order to generate various constant current values in this way. It can e.g. B. it can be provided that the current source can generate 2 currents of 0.5 mA, 1 mA and 2 mA for measuring the different sensor types.

The following table shows examples of various passive temperature sensors and an active signal generator (0 to 10 volts) and an adjustable resistor, the minimum and maximum working temperatures and suitable values for the measuring current and the gain factor of the measuring amplifier 8 are given.

table

In the table, a measuring current of 0 0 mA means 1 means 0.5 mA, 2 means 1 mA, and 3 means 2 mA. A measuring amplifier factor of 0 means 12 times amplification, 1 means 6- times amplification, 2 means 3 times amplification, 3 means 2.4 times amplification, 4 means 2 times amplification, 5 be indicates 1.5 times amplification, 6 means 1.2 times amplification and 7 means a gain factor = 1 for the measurement of 0 to 10 volts.

The measuring times are preferably in the range from 2 ms to 100 ms. Depending on the desired resolution and the permissible Suitable measuring times or measuring frequencies can occur be chosen.

The control of the current source 2 and the evaluation unit 6 and the selection of the channel 30 to be measured is carried out via the microcontroller and the SPI interface 40 to 46 . The ASIC 1 receives the control signals at the control word decoder 14 and converts them into corresponding commands for setting the measuring current, for selecting the channel, for selecting the amplification factor and for determining the measuring time. The digital output signal of the pulse counter 12 is transferred to the SPI encoder 18 and is output by the latter via the SPI interface 46 to the microcontroller.

The present invention provides an integrated analog Digital converter, the analog and digital components for pas active and active devices in an integrated circuit united and makes it possible to have a single component with meh provide more channels, to which any passive and active Elements can be connected. In particular it is featured see the analog-to-digital converter according to the invention in one Heating control system to use the connected active and to be able to process passive sensors digitally. To everybody Channel can have different temperature sensors as well as others Standard interfaces or signal transmitters can be connected. Each channel is suitable for every type of sensor. By switching of the measuring amplifier can send the measuring signal to the work area of the voltage-frequency converter can be adapted. The passive ones Sensors of the analog-digital converter according to the invention be supplied with a constant measuring current. The external Wiring of the ASIC is based on a few components for interference pressure, the integration capacitor and the microcontroller limited. With the integrated analogue Di according to the invention gital-converter was also overcome the prejudice that the processing of high voltages and currents in electro African semiconductor components disadvantageous on their size and Price affects. With the present invention was not only realized the goal of creating an analog-to-digital converter, that evaluate both passive and active devices can, but a circuit design was also developed, that manages with a minimal number of components and integration of the entire circuit allows.  

The in the above description, the claims and the Features disclosed can be drawn individually as well in any combination for realizing the invention in their various configurations.

Claims (13)

1. Analog-digital converter with at least one channel ( 30 ) for connecting active and passive devices, with a switchable current source ( 2 ), an evaluation unit ( 6 ) and a channel control unit ( 4 ), in which
the current source ( 2 ) can be connected to the channel ( 30 ) via the channel control unit ( 4 ) if a passive device is connected to the channel in order to generate a passive analog measurement signal,
the current source ( 2 ) can be deactivated when an active device, which emits an active analog measurement signal, is connected to the channel ( 30 ), and
the passive or active analog measurement signal can be applied to the evaluation unit ( 6 ) via the same channel ( 30 ) and the channel control unit ( 4 ) in order to derive a digital measurement value. 2. Analog-digital converter according to claim 1, characterized in that the current source ( 2 ), the evaluation unit ( 6 ) and the channel control unit ( 4 ) form an integrated circuit ( 1 ). 3. Analog-digital converter according to claim 1 or 2, characterized in that it has a plurality of input / output channels ( 30 ). 4. Analog-digital converter according to claim 3, characterized in that the channel control unit ( 4 ) has a first input multiplexer which is connected between the current source ( 2 ) and the input / output channels ( 30 ). 5. Analog-digital converter according to claim 3 or 4, characterized in that the channel control unit ( 4 ) has a second input multiplexer which is connected between the input / output channels ( 30 ) and the evaluation unit ( 6 ). 6. Analog-digital converter according to one of the preceding claims, characterized in that the current source ( 2 ) is adjustable in order to generate a measuring current adapted to the connected passive device. 7. Analog-digital converter according to one of the preceding claims, characterized in that the evaluation unit ( 6 ) has a measuring amplifier ( 8 ) with an adjustable gain factor. 8. Analog-digital converter according to claim 7, characterized in that the evaluation unit ( 6 ) has a voltage-frequency converter ( 10 ). 9. Analog-digital converter according to claim 8, characterized in that the evaluation unit ( 6 ) has a pulse counter ( 12 ). 10. Analog-digital converter according to one of the preceding Claims characterized by a tax device for setting at least one of the fol parameters: measuring current, measuring time, measuring amplification, Channel. 11. Analog-digital converter according to one of the preceding claims, characterized by an active and a passive mass ( 32 , 34 ) for the measurement of the active or the passive devices. 12. Analog-digital converter according to one of the preceding Claims, characterized in that the passive devices variable resistances, esp special temperature sensors include. 13. Analog-digital converter according to one of the preceding Claims, characterized in that the active devices include analog signal generators.