FR2625822A1 - DEVICE FOR INTRODUCING DATA IN A MICROPROCESSOR, IN PARTICULAR FOR CONTROLLING AN ELECTRICAL APPLIANCE - Google Patents

Abstract

The analog data to be introduced into a microprocessor 10 are represented by resistance values. The discharge time of a capacitor 16 is determined through a reference resistor 17 and through the resistor 18 to be measured which is in series with the resistor 17. The reference resistor 17 constitutes a protection of the microprocessor against the parasitic currents which. could flow through resistor 18 to be measured.

Description

iof 2625822 '

  DEVICE FOR INTRODUCING DATA IN

  A MICROPROCESSOR, PARTICULARLY FOR

  CONTROL OF AN ELECTRICAL APPLIANCE

  The invention relates to a device for introducing data into a microprocessor, in particular for controlling an electrical appliance such as a washing machine. For the introduction of analog data into a microprocessor it has already been proposed (British Patent 2,020,934) to represent the data by resistance values and to arrange this resistance in series with a capacitor, the data entered into the microprocessor being the time taken by the charge of this capacitor to reach a predetermined value when charging or discharging through the resistor, the

  microprocessor transforming this time into a numerical value.

  Since the time given above depends on the value of the resistance, the accuracy of the data depends on the accuracy of the resistance. In order to overcome this inaccuracy, a resistance of precisely known value is also provided and the charging or discharging time is determined, on the one hand, through this specific resistor and, on the other hand, through the resistor. representing the analog data to be introduced, the microprocessor calculating the product of the value of the precise resistance by the ratio between these

two times.

  So. not only the imprecision on the resistance values but also the inaccuracies due to the dispersions on the characteristics of the microprocessors are overcome. In known embodiments of such data input devices, each terminal of the resistor to be measured is connected directly to an input of the microprocessor. It has been found that in washing machines, where parasitic currents can circulate, this arrangement does not insure

  sufficient security for the microprocessor.

  The invention overcomes this disadvantage.

  The device according to the invention is characterized in that the resistance to be measured is connected to an input of the microprocessor via the measuring resistor with which it is thus in series when the capacitor is charged or discharged through it. measuring resistance, the data being determined by measuring the charging or discharging time, on the one hand, through the precise resistance and, on the other hand, through the series assembly of this precise resistance and resistance To measure, the microprocessor calculating the time difference then the product of the ratio of this difference on the first time by the value of ia

precise resistance.

  This arrangement makes it possible to protect the microprocessor against the strong currents flowing in the resistance to be measured, the precise resistance constituting a protection to

the microprocessor input.

  It is possible to connect the precise resistance to the input of the microprocessor via a

  additional resistance 'of protection.

  The data constituted by the position of the slider of a potentiometer can also be accurately entered into a microprocessor, although the value of the total resistance of the potentiometer is not known with great precision. For this purpose, the charging or discharging time is determined by means of the total resistance of the potentiometer in series with the measuring resistor, the charging or discharging time through the partial resistor (of which one terminal is the slider) in series. with the measuring resistor, and subtract from each of these times, the charging or discharging time through the measuring resistor, and then the relationship between these

  time (thus decreased) to obtain the cursor position.

  The device according to the invention applies to household appliances, in particular to the control programmers of washing machines. The resistance whose value is to be determined is, for example, a thermistor for measuring the temperature of the water in a washing machine. The potentiometer is used for example to display a desired value of rotation speed of the drum for spinning or a load of laundry, the microprocessor determining the various parameters of

  operation of the washing machine according to this load.

  Other features and advantages of the invention

  will appear with the description of some of its modes of

  embodiment, this being done by referring to the attached drawings in which - Figure 1 is a diagram of a microprocessor and a data input device according to the invention, and - Figure 2 is a diagram. relating to

  operation of the device of Figure 1.

  The microprocessor 10 (FIG.

  input 11 and four control outputs 12, 13, 14 and 15.

  At the input 11 are connected, via a resistor 21 for protecting said input: an armature 162 of a capacitor 16. and a first terminal 171 of a resistor 17 of reference value R0. At the second terminal 172 of the resistor 17 is connected a first terminal 181 of a resistor 18 of value Rx to be measured, a first end terminal 191 of a potentiometer 19 of total resistance P, the position of which is to be determined. slider, and the

  collector 221 of a transistor 22 of the NPN type.

  The second armature 161 of the capacitor 16, of capacitance C, is connected to a terminal 20 on which is applied

  a continuous potential V of reference.

  This second terminal 182 of the resistor 18 to be measured is

  connected to the collector 231 of another transistor 23 of the NPN type.

  The second end-port 192 is also connected to the collector 251 of an NPN transistor 25. Similarly, the plug, or slider, 193 of this potentiometer 19 is connected to the

  collector 241 of a transistor NPN type 24.

  Transmitters 223, 233, 243 and 253, respectively, of transistors 22, 23, 24 and 25 are connected to ground. The bases 222, 232, 242 and 252 respectively are connected to the outputs 12, 13, 14 and 15 of the microprocessor 10 by

  through resistors respectively 52, 53, 54 and 55.

  To measure the value R of the resistor 18, the x terminal 11 is taken to the potential Vcc, which makes it possible to discharge the capacitor 16 through the resistor 21. Then the potential Vcc is removed from the terminal 11, which again becomes the same. 'Entrance. Then the output 12 is raised to the potential Vcc, which makes the transistor 22 conductive and allows to bring to the ground the end 172 of the resistor 17 reference; at the same time the outputs 13, 14 and 15 are grounded, the transistors 23, 24 and 25 thus being kept in the off state,

  that is, the terminals 182, 193 and 192 are "in the air".

  Under these conditions, the capacitor 16 is charged through the resistor 17. At the instant t = 0 corresponding to the beginning of the connection of the output 12 to the potential Vcc, the potential at the input 11 is Vcc (that of the terminal 20 ); then this potential at the input 11, which is represented by the curve 30 in Figure 2, decreases to reach a value V0, which is the measurement threshold of the input of the microprocessor, at the end of time t1. The microprocessor transforms this time t1 into

  a number that is kept in memory.

  Then the capacitor 16 is discharged again by temporarily connecting the terminal 11 to the potential Vcc; then this capacitor 16 is charged through the resistor 18 in series with the resistor 17 by making the transistor 23 conductive through a voltage Ve applied to the output 13 while leaving the outputs 12, 14 and 15 to ground. so that the transistors 22, 24 and 25 are blocked. The potential on the terminal 11 is then represented by the curve 31 in FIG. 2;

  It reaches the value V0 at time t'1.

  Time t1 obeys the following relation

t1 = RoC.K.

  In this formula K is a constant that depends

of V0 and the microprocessor.

  In the same way, the time satisfies you at the relation t'1 = (Rx + R) C. K. Then calculate the difference t "1 between t 'and t = t" = tt R CK G In these conditions we can write 1x: R0 t "t1 Thus the precision on the value R of the resistance 18 depends on the precision on R0, which is for example + 1%, and the accuracy, which can be large, on the values t 'and t On the other hand, the measured value is independent of V0 (input threshold of the microprocessor) and of C The resistor 18 is, in one embodiment, a thermistor for measuring the temperature of the water lying

in the tub of a washing machine.

  If strong currents, harmful to the

  microprocessor, flow in the resistor R, the current which.

  the microprocessor is terminated by the presence of the reference resistor 17 and the resistor 21. The resistor 17 can in itself suffice for the protection of the microprocessor 10, that is to say that the value can be conferred.

no resistance 21.

  Instead of the transistors 22, 23, 24, 25, it is possible to connect the various terminals of the resistors directly to the outlets 12, 13, 14 and 15 provided that suitable potentials are applied to these outlets. For example when one wants to charge the capacitor 16 through, the resistor 17 whose terminal 172 is directly connected to the terminal 12, then it is necessary to connect said terminal 12 of the ground and put the terminals 13, 14 and 15 in the air (Terminals that would be, in this embodiment, connected directly to the terminals respectively 182, 193 and 192). But the advantage of providing transistors, or other types of controlled switches, is to allow better measurement accuracy because the latter is not disturbed by the leakage currents of the microprocessor. More specifically, an output of the microprocessor, for example that of reference 13, "in the air", means that the resistance between this terminal 13 and the ground has an infinite value. But in practice, because of leakage currents, this is never the case, which disturbs the measurement. By cons with the transistors 22, 23, 24, 25 which play the role

  decoupling switches, the measurement is of better quality.

  To determine the position of the slider 193 of the potentiometer 19 is carried out in a manner similar to that described above, namely that is determined firstly the discharge time t1 through the resistor 17. Then the capacitor is discharged 16, and is recharged through the total resistance of the potentiometer 19 in series with the resistor 17 by making the transistor 25 conductive through a potential V c on the terminal 15, the other terminals 12 to 14 then being grounded, so that the corresponding transistors 22, 23 and 24 are blocked, and the time t2 at which the potential on the terminal 11 reaches the value V0 is determined. Then, after having discharged the capacitor 16 again, on the terminal 14 a potential Vcc is generated so that the transistor 24 is conducting and the terminals 12, 13 and 15 are grounded so that the. Corresponding transistors 22, 23 and 25 are blocked and the time T 2 at which the potential on terminal 11 reaches the value V 0 is determined. The value of the resistance between terminals 19 and 193 is C0 P. We can write:

t2 (P + RO) C.K.

t2 t1 = P.C.K.

t2 1 (P + R) C.K.

t2 = (<P + R0) O. K.

t2 - t !: P.C.K.

  The position of the cursor 193 is represented by the number which is independent of the value P of the total resistance of the potentiometer 19. It is thus possible to accurately display a quantity although the value of the total resistance of the potentiometer is known only with low precision The potentiometer 19 can be used in a washing machine to display the desired temperature of the wash water, to display the desired speed of rotation for the drum during spinning or to display the load of laundry introduced into the drum, the microprocessor 10 then determining the various parameters of the washing as a function of

this charge thus displayed.-

  The microprocessor 10, the capacitor 16, the resistor 17 and the resistors 21, 52, 53, 54, 55 and the transistors 22, 23, 24, 25 at the same time as the supply source of the terminal 20 are usually arranged on a same printed circuit board 40 which then has four inputs 41, 42, 43 and 44 connected. to the collectors of the transistors respectively 22, 23, 24 and 25. Thus the resistor 18 will be connected between the terminals 41 and 42- while the socket 193 is connected to the terminal 43. The potentiometer 19

  is connected between terminals 41 and 44.

Claims (12)

  A device for introducing analog data into a microprocessor (10), which data is represented by resistance values, which device comprises a capacitor (16) and a resistance of. reference (17), allowing, with the microprocessor, to determine the charging or discharging time. a capacitor (16) for measuring said resistance value, characterized in that the resistor (18, 19) to be measured is connected to the input (11) of the microprocessor (10) via the resistor (17) reference.   2. Device according to claim 1, characterized in that the microprocessor determines the value (1Rx) of the resistor to be measured by the following relation 1 = t '- te tl R being the value of the resistor. The charging or discharging time through the series set of the resistor to be measured and the reference resistor (17) and t1 is the charging or discharging time through the reference resistor. 3. Device according to claim 1 or 2, characterized in that the reference resistor (17) is connected to the input (11) of the microprocessor via a protection resistance (21).   4. Device according to claim 1, 2 or 3, characterized in that the terminals (18, 182) of the resistor (18) to be measured are each connected to a reference potential, for example ground, via of switches (22, 23) controlled by the microprocessor (10) so that, for a state of one switch, and the opposite state of the other switch, the capacitor (16) can charge or discharge at through the resistance of reference and not through the resistance to be measured and that for the other states of these switches the capacitor (16) charges or discharges through the reference resistance in series with the resistor. To measure.   5. Device according to claim 4, characterized in that the switches (22 and 23) are transistors whose base is connected to a corresponding output (12, 13) of the microprocessor. 6. Device according to claim 4 or 5, characterized in that the control electrode of each switch. controlled is connected to a microprocessor output   through a resistor (52, 53) of: protection.   7. Device according to any one of   preceding claims, for the purpose of. reading the position   the slider (193) of a potentiometer (19), characterized in that the time t2 charging or discharging the capacitor (16) through is determined. the total resistance of the potentiometer in series with the reference resistor, in that one determines the charging or discharging time of the capacitor (16) through the series set of the reference resistor (17). ) and the resistance presented by the potentiometer (19) between an end terminal (191) and the slider (193) and in that the position of the slider is determined by the formula: = t'2 - to≤ < 2 - tt being the charging or discharging time of the capacitor (16) i   in the reference resistor (17).   8. Device according to claim 7, characterized in that the end terminals of the potentiometer and the slider (193) are connected to a reference potential, such as ground, via respective switches controlled by corresponding outputs (12, 14, 15) of the microprocessor (10).   9. Device according to any one of the   preceding claims, characterized in that the accuracy   on the reference resistance is of the order of + 1 96.   10. Application of the device according to any one   claims 1 to 6 to the determination of the value of a   thermistor for measuring the temperature of the water in the tank a washing machine.   11. Application of the device according to claim 7 or 8, the display of a set value for the control of a washing machine such as the desired temperature for the wash water, the desired speed for the rotation of the washing machine. drum when   spinning or loading the laundry into the drum.   12. Device for introducing analog data into a microprocessor (10), these data being represented by resistance values, comprising a capacitor (16) mounted with the resistance to be measured in such a way that the microprocessor determines the time taken by the charging the capacitor (16) to reach a predetermined value (V0) when the capacitor charges or discharges through the resistor to be measured, characterized in that the terminal of the resistor to be measured opposite the input (11) ) of the microprocessor is connected to a terminal which is brought to a determined potential, for example that of the ground, by means of a switch controlled by the microprocessor (10).