CH653131A5 - Meter temperature in value digital living body. - Google Patents

Abstract

The heat-sensitive element (2) of the probe (1) controls a calculator (Ca) converting into digital value the temperature measured by said element. The transmission of data from the calculator (Ca) to a receiver (R) is controlled by a gate (P1) which enables the transmission to take place only after a contact controller (Co) has verified that the probe is in contact with the body of which the temperature is to be measured and that the probe has remained uninterruptedly in contact with said body during a predetermined duration of time at least equal to the time required by the heat-sensitive element (2) to reach the temperature of said body. Thereby, the apparatus insures that any temperature value which does not correspond to the real temperature to be measured is not transmitted to the receiver in case of accidental contact interruption between the probe (1) and said body.

Description

       

  
 

** ATTENTION ** start of the DESC field may contain end of CLMS **.

 



   CLAIMS
 1. Apparatus for measuring the temperature in numerical value of a living body, of the type comprising a thermometric contact probe (1) comprising a thermosensitive element (2) whose electrical characteristic varies as a function of temperature, and a computer ( Ca) controlled by this probe, to supply, in electrical form, the digital value of the temperature measured analogically by the probe, characterized in that it comprises, associated with the probe (1), a contact controller (Co) for check that the probe (I) is in uninterrupted contact with a part of the living body whose temperature it is to measure, for a predetermined period, sufficient for the probe to have time, given its thermal inertia, to effectively take the temperature of this part of the body,

   this contact controller (Co) comprising means (Pi) for controlling the transfer of information from the computer (Ca) to at least one receiving member (R).



   2. Apparatus according to claim 1, characterized in that it comprises a delay means (16) for authorizing the transfer of information from the computer (Ca) to at least one receiving member (R) only after lapse of a lapse predetermined time of uninterrupted contact of the probe (I) with the above-mentioned part of the body.



   3. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises a contact detector (3, 6) of the probe (1) with the aforesaid body which is arranged on the probe and arranged to control the controller contact (Co).



   4. Apparatus according to claim 1 or 2, characterized in that it comprises comparator means (ICi) for comparing the temperature measured by the probe (Te), to a stored reference temperature (To) and different from the ambient temperature , these comparator means (HERE) belonging, with the probe itself (2, 63), to the contact controller.



   5. Apparatus according to claim 1 or 2, characterized in that it comprises comparator means (65) for comparing between them two to two temperatures measured successively by the probe (Ti; Ti-1), these comparator means (65 ) belonging, with the probe itself (1), to the contact controller.



   6. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises two neighboring electrical contacts (5, 7), isolated from each other and arranged on the surface of the probe (1), in the region of the measuring part (2) of the probe, so that the contact of this part with the body (29) above establishes an electrical connection between these contacts (5, 7).



   7. Apparatus according to claim 6, characterized in that the two aforesaid contacts (5, 7) are in an electrical circuit comprising a voltage source (11) connected to a logic circuit (30) whose state is a function of voltage across its terminals, in series with this source and a resistor (31) of high value, this circuit thus being closed only when the probe is in contact with the aforementioned body.



   8. Apparatus according to claim I or 2, characterized in that the contact controller comprises, arranged in the region of the measurement part (2) of the probe (la), an electric capacitor part (32, 33) disposed in a capacitive circuit (35) and comprising an armature (32) covered with an insulating layer (33) intended to make contact with the above-mentioned body (29) at the same time as the probe (la), this body (29) forming then the other armature of the capacitor, so that the variation in total capacity of the circuit is modified when the probe (la) is in contact with the above-mentioned part (29) of the body.



   9. Apparatus according to claim I or 2, characterized in that the contact controller comprises two neighboring electrodes (45, 46), of different chemical nature, arranged on the surface of the probe, in the region of its measurement part ( 2), these electrodes being arranged in a control circuit (FIG. 4) which comprises means for amplifying (50) the voltage of electrochemical origin appearing between these electrodes when they are brought into contact with a wet part, forming electrolyte, of the aforementioned body, and which further comprises a logic element (55) whose state varies in response to variations in this voltage.



   10. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises two electrical contacts (60, 61) carried by the probe, arranged close to one another and movable with respect to the other, at least one of these contacts (60, 61) being elastically movable relative to the other, so that a pressure exerted on the aforesaid body by this sensitive part produces the displacement of the mobile part of these contacts and the electrical contacting of these two contacts and the closing of a control circuit.



     he. Apparatus according to claim 5, characterized in that the contact controller is arranged to authorize the transfer of information from the computer to the receiver when the first of these temperatures is at least equal to the second (fig. 6).



   12. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises comparator means reacting when the temperature measured by the probe passes from a practically stationary value to a higher value (fig. 9).



   13. Apparatus according to claim 5, arranged to perform cyclically several preliminary temperature measurements, before an actual temperature measurement, and to store the successive digital values of these preliminary measurements, characterized in that it comprises a counter (72 ) arranged to be incremented when two successive preliminary values (Tj; Tm) are equal, and to be reset to zero when they are different, means (74, 75) interrupting the storage of said values when the content of the counter (72) reaches a predetermined value, the last memorized value (Tm) then constituting the actual measured value.



   14. Apparatus according to claim 1, wherein the computer (Ca) is arranged to periodically generate a digital signal whose value varies with the temperature measured by the probe, characterized in that the contact controller is arranged to control the transfer of successive digital values of said signal to at least one receiving member, for example a memory and / or a digital display means, in response to the detection of contact between the probe and the above-mentioned body (FIG. 6).



   15. Apparatus according to claim 14, characterized in that the contact controller comprises a circuit (65; IC1) arranged to periodically compare, in pairs, the successive values of said digital signal (Ti; Ti-l) representative of the temperature measured by the probe (2), and produce said transfer when the difference between these successive values goes from zero to a positive value.



   Various types of electronic thermometers are known, comprising a thermometric probe intended to be brought into contact with a body whose temperature is to be measured. However, these known thermometers have the disadvantage of requiring the user to keep the probe in contact with the body in question for a sufficient time. If keeping the probe in contact with said body is too short for the measurement, the electronic circuits cannot calculate the correct digital value of the temperature to be measured, which can lead to disturbed operation and loss of values of temperatures previously stored and still required.



   The present invention aims to provide an apparatus for measuring the temperature in numerical value of a living body, which is free from this drawback, that is to say which only makes correct measurements, and its subject is a apparatus which conforms to claim 1.



   The accompanying drawings show, schematically and by way of examples, several embodiments of the temperature measuring device according to the invention.



   Fig. I is a diagram of an embodiment of the apparatus illustrating the principle of the invention.



   Fig. 2, 3, 4 and 5 illustrate different variants of the probe.



   Fig. 6, 7, 8 schematically represent three other embodiments of the device.



   Fig. 9 is an explanatory diagram of the operation of the embodiment according to FIG. 8.



   In the embodiment according to fig. I, the apparatus comprises a thermometric probe I in which is arranged a thermosensitive element 2 (thermistor) whose electrical characteristic (the resistivity) varies as a function of the temperature. On this thermometric probe and in the vicinity of the part in which the element 2 is located, there is disposed a contact detector constituted by a switch 3 provided for closing when the probe is applied against a part of a living body. whose temperature we want to determine. We see that this contact or switch 3 pivots at 4 on a metal part 5 of the probe, while when this switch 3 closes, it comes into contact with a part 6 fixed on the metal body of the probe, visible at 7.

  Part 5 is connected by a conductor 8 to another part of the device, as will be seen below, while part 7 is connected by a conductor 9 to another part of the device, as we will also see further. The heat-sensitive element 2 is connected by conductors 10 to other parts of the device as will be explained below.



   The apparatus roughly comprises a part Co which constitutes a controller for contact of the probe with the body whose temperature is to be measured and a receiver R which is intended to receive, in digital form, the measured temperature of the body with which the probe is put in contact. A Ca calculator, the function of which is to convert the temperature values given in analog form by the element 2 into digital form by means of the conductor 10. A gate Pi is arranged between the Ca calculator and the receiver R. In a variant, the door Pi could be replaced by a door P2 arranged between the probe and the computer Ca.

  The Co controller includes a circuit which will now be described and whose function is to ensure that there is contact between the probe and the body whose temperature is to be measured and that this contact remains uninterrupted for a period of sufficient time to be sure, given the thermal inertia of the probe, that it has actually taken the temperature of the part of the body with which it is in contact (time constant of the probe). It is therefore a question of ensuring that the contact between 3 and 6 exists and that it is maintained without interruption during this period of time at least. For this, the controller Co comprises the following circuit: an electrical power source 11, the positive side of which is connected to the part 7 of the probe by the conductor 9; the negative side is grounded.

  The circuit also comprises a transistor 12, the base of which is connected to the conductor 8 through a resistor 13 of for example 1 kΩ. The conductor 8 is connected to ground through a resistor 14 of high value, for example 1 Mn. A diode 15 connects the conductor 8 to an armature of a capacitor 16 through a resistor 17 of for example I MQ. The value of this resistance is chosen to determine the imposed duration during which the contact between 3 and 6 must be uninterrupted. The other armature of the capacitor 16 is grounded.



  The capacitor may have a capacity of for example 500 uF.



  The emitter of transistor 12 is connected to a point located between resistor 17 and capacitor 16. This connection is used to quickly discharge capacitor 16 in the event that, during the imposed period of non-opening of the contact between 3 and 6, a opening would happen accidentally. The collector of transistor 12 is connected to ground via a resistor 18 of for example 22 Q. The circuit considered also comprises a voltage comparator 19.



  At 20 we see the inverting input of comparator 19 and at 21 the non-inverting input of this comparator. The voltage of the source 20 is divided by means of three resistors 22, 23, 24, the last of which is adjustable so that the voltage at 20 corresponds to the charging time desired for the capacitor 16. The input is connected to the output of the resistor 17 and at the input of the capacitor 16, as well as at the emitter of the transistor 12. The comparator is supplied by the source 11 via the conductors 25, 26.



   The operation of the circuit described is as follows. When the contact is established between 3 and 6, the capacitor 16 begins to charge through the diode 15 and the resistor 17. As it charges, its voltage at 21 is compared to the voltage chosen at 20. As soon as the voltage at 21 exceeds the voltage at 20, the output 27 of the comparator 19 changes logic level from zero to 1. We will see later that this change in level constitutes a signal acting on the gate Pi. This case corresponds to that where the contact between 3 and 6 remained uninterrupted for the entire required time which is, as indicated above, at least equal to the time constant of the probe.

  If we are in the case of a change resulting from the fact that the contact between 3 and 6 is broken before the imposed time has elapsed, then, when the contact is opened between 3 and 6, the base of the transistor 12 which was connected to the positive terminal of the source 11 by the conductor 8, which blocks the transistor, is now connected to the ground via the resistor 14, which causes the rapid discharge of the capacitor 16 through the transistor and the resistor 18. Consequently, the comparator 19 cannot deliver an output signal at 27 and, consequently, the gate Pi cannot be actuated. The aim is indeed to open this door only when it is established that the contact between 3 and 6 has remained uninterrupted for the fixed duration.



   When the door Pi is opened, the calculated digital value of the temperature supplied by the computer Ca is authorized to be transferred to one or more receiving members R, for example a display and / or a memory. Of course, as already mentioned above, the door Pi disposed between the computer Ca and the receiver R could be replaced by a door P2 disposed between the probe and the computer Ca. The operation would be similar, simply act on the input of the calculator instead of acting on its output.



   It can be seen from the above description that the contact controller Co ensures that the transmission of data (that is to say of the temperature as a digital value) from the computer to the receiver is only authorized if the contact between 3 and 6 is closed and remains closed continuously for the predetermined period of time corresponding to the device setting. In this way, we are sure that the digital temperature value transmitted by the computer to the receiver is that of the temperature of the body with which the probe is in contact, because this probe has been given time to take the temperature of this body taking into account its own time constant.



   Fig. 2 shows a first embodiment of the probe which can be used in practice, that illustrated in FIG. I and comprising a switch 3, 6 having been given to facilitate understanding but not corresponding to the needs of practical use. In fig. 2, we find the heat-sensitive element 2 and we see that the metal parts 5 and 7 are mechanically connected together by an insulating part 28 which isolates them from each other. When a part 29 of a living body whose temperature is to be measured is applied to the probe, so as to touch both part 5 and part 7, an electrical connection is established between these parts 5 and 7 through part 29 of the body. The resistance of the body part 29 between 5 and 7 can be designated by Rc.



   In the case of such a contact detection means between the body 29 and the probe 1, it is necessary to add to the circuit according to fig. 1 an operational amplifier 30 mounted as an impedance adapter between the conductor 8 and the point A in FIG. 1. A resistor 31 of for example 10 Mn is disposed between the non-inverting input 21a of 30 and the ground. This input is also connected to the conductor 8. For the rest, the circuit is identical to the case of FIG. 1.



   In the example of a probe shown in fig. 3, the layout is as follows. The body of the probe is made of insulating material. Inside its measuring end is on the one hand the thermosensitive element 2 and, on the other hand, a metal part 32 which constitutes an armature of a capacitor, the dielectric of which is constituted by part 33 in insulating material of the probe. When a part 29 of the body whose temperature is to be measured is brought into contact with part 33, this part 29 closes the second armature of a capacitor whose dielectric is at 33 and the first electrode at 32. This has been symbolized capacitor at 34. The circuit includes an LC 35 oscillator of which only the capacity has been indicated, at 36.



  The capacitor 34 is connected to the input of the oscillator on the one hand by a conductor 37, itself connected to 32, and, on the other hand, to 29 via a conductor 38 leading to a metal sheath 39 of the probe la. This sheath is arranged as seen in the drawing, so that the part of the body 29 is in contact with it and extends as far as the metal part 32 to close the capacity symbolized by 34. It is understood that when the part 29 is brought into the position shown in FIG. 3, the capacitance 34 is in parallel with the internal capacitance 36 of the oscillator 35, which disrupts the oscillator, causing an alternating signal at the output 40 of the oscillator, signal which is rectified by a rectifier 41 and sent at point A in fig. I via a resistor 42 and a Smitt trigger 43.

  A filter element (capacitor) 44 is connected between 42 and 43 on the one hand and ground on the other, to equalize the DC voltage supplied at point A. The role of element 44 is to ensure that the signal delivered by 43 is clean, that is to say has a practically vertical flank. For the rest, the circuit is similar to that of FIG. I and the device ensures, as in the first example, that the transmission from the computer to the receiver is made only if the contact of 29 with the probe exists and is maintained for the desired duration.



   In the example of a probe according to fig. 4, the provision is as follows. The probe comprises a metal sheath 45 of a metal such as zinc and a cap 46 of another metal such as gold or another metal whose surface is golden. An insulating part 47 separates 45 from 46. The two metals of 45 and 46 are chosen such that when bringing a part 29 of the body whose temperature is to be measured in contact with both 45 and 46, if this part is wet and forms an electrolyte, the parts 45, 46 and 29 constitute a battery generating a certain voltage. One of the electrodes, 45, of this cell is connected to ground by the conductor 48, while the other electrode constituted by 46 is connected by a conductor 49 to an input of an amplifier 50, via a resistance 51.

  The other input of this amplifier is connected to ground via a resistor 52 and a conductor 53. The source of electrical power is shown at 11, as in FIG. 1. The amplifier 50 is supplied by the source, as can be seen in the drawing. A feedback resistor 54 determines the gain of the amplifier 50.



  The output of the amplifier 50 gives an electrical signal proportional to the voltage supplied by the battery 45, 29, 46. This signal acts on an input of a comparator 55, via a resistor 56. A divider of voltage, consisting of a resistor 57 and a variable resistor 58, supplies the other input of comparator 55 which is supplied by source 11. The output of the comparator is connected to point A of the circuit according to fig. 1. Here again, the device authorizes the transfer of information from the computer to the receiver only if the contact is made by 29 between 45 and 46 and remains uninterrupted for the time fixed for the temperature measurement operation.



   Fig. 5 illustrates a practical embodiment of the probe according to FIG. 1.



  The body 59 of insulating material of the probe is slightly flexible and it is disposed inside two metal parts 60, 61 electrically insulated from one another and which, at their left end in FIG. 5, are normally slightly distant from each other.



  It is near this interval between 60 and 61 that the thermosensitive element is located 2. A buffer made of elastic material 62 constantly tends to separate the parts 60 and 61 from one another. When the end of the probe between two parts 29a, 29b of a body whose temperature is to be measured (for example the two lips between which the probe is introduced into the mouth), the end of this probe flattens slightly and the contact electric is established between 60 and 61. Under these conditions, the circuit is identical to that of fig. 1.



   In the example according to fig. 6, the probe is shown at 63. It does not have any contact detector element, unlike what is the case in the previous examples. It simply contains, inside its measuring end, the heat-sensitive element 2.



  This thermosensitive element 2 is connected to an A / D computer such as
This in fig. 1. The door corresponding to Pi in fig. I is replaced here by a door 1C3 (for example of the type 74C373 of National Semi conductors) .- This door is intended to let pass the information coming from the Ca computer when it receives the command from the driver 64. The computer output Ca is also connected to an input of a comparator ICI (for example of the 74C85 type from National Semiconductors) in order to compare the digital value Te of the temperature measured in 2, delivered by Ca, to a reference temperature TO stored in a memory Mo. When the comparator IC1 finds that Te> TO, it delivers by its output a signal at point A (fig. 1). Furthermore, the conductor 64 is connected to point B (fig. 1).

  For the rest, the circuit is similar to that of FIG. 1 and the operation too.



   In the example according to fig. 7, we see a probe 63 similar to that of FIG. 6, a computer Ca similar to that of FIG. 6, in IC1 is a comparator similar to HERE in FIG. 6. We see at 65 a shift register whose function is to keep in memory the last digital temperature value Ti delivered by the computer. Its function is also to keep in memory the previous value Ti
 1, so that the ICI comparator can constantly be supplied with two consecutive measured digital values Ti and Ti- 1. When the ICI comparator finds that Ti> Ti-1, it delivers a signal by its output which goes to point A (see fig. 1). Door 1C3 receives its command from point B (see fig. 1). For the rest, the circuit and the operation are the same as in the case of FIG. 1.



   Fig. 8 illustrates, in the form of a block diagram, a final embodiment. As in the previous example, the thermometric probe only comprises the thermosensitive element 2 which acts on the computer Ca, which transmits to a memory 66 the value Tj which it has just calculated. The memory Tj periodically sends the value it has just received to a comparator 67. Furthermore, the memory 66 transmits the value Tj to another memory 68 when a gate 69 authorizes it to do so. This memory 68 stores a temperature Tm previously measured by Ca. The value of Tm is sent regularly to the comparator 67. When this comparator finds that Tj> Tm, it gives an opening signal to the gate 69, via an OR 70 logic gate.

  Similarly, if the comparator 67 finds that Tj <Tm, it gives the opening signal to the gate 69 via the OR logic gate 70. Finally, if the comparator 67 finds the equality between Tj and Tm, it gives a signal at-71 which has the effect of incrementing a counter 72 by one unit. This counter 72 is reset to zero by the driver 73 each time the logic gate 70 lets the signal pass, that is to say - say each time there is inequality between Tj and Tm.



   In 74 there is a memory in which a number has been memorized which is that of the number of successive measurements which it is admitted to be sufficient to allow validation of the measured temperature if it has remained equal to itself during this number of measures. A comparator 75 therefore determines whether the number reached in 72 has become equal to that stored in 74 or if it has not. If it is equal, the comparator 75 gives the driver 76 a signal to a door 77 opening the latter to allow the value Tm to pass through the receiver R which can be constituted by a memory and / or a display. This value Tm is then the validated measured value of the temperature.



   However, so that the device can distinguish automatically if it is before the start of the curve shown in fig. 9 or in the final part thereof, because in both cases the device finds during several successive measurements a zero difference between each measurement and the previous one, there is provided a contact 78 placed between the output of the comparator 75 and door 77. This contact 78 is normally closed and the operator must act on it to reopen just before bringing the probe into contact with the body. This contact is timed, that is to say that it closes automatically after a few seconds when one is in the ascending part of the curve according to fig. 9.

  Consequently, there is no longer any indeterminacy and the device operates solely on the basis of the successive temperature comparisons and then determines without error the moment when we arrived in the final part of the curve where the growth is zero.



   The diagram according to fig. 9 illustrates what happens by these successive measurements, on the ordinate the temperatures are indicated and on the abscissa the successive measurements made at equal time intervals.



   We see that in the first phase, as the probe sees its temperature increase and approach that of the body whose temperature we want to determine, the transfer from Tm to R will be blocked. It is only when we have, for several successive measurements, equality of Tj to Tm, which is represented by the final part of the curve, that the measurement will be validated and that Tm will be transferred to R.



   The operating difference between this embodiment and that according to fig. I is that we do not have here an element fixing the minimum duration of the measurement operations, but that the necessary duration is provided by the measurements themselves, that is to say by the time necessary to arrive at temperature equality for a sufficient number, for example 5 or 6, of successive measurements.


    

Claims (15)

 CLAIMS  1. Apparatus for measuring the temperature in numerical value of a living body, of the type comprising a thermometric contact probe (1) comprising a thermosensitive element (2) whose electrical characteristic varies as a function of temperature, and a computer ( Ca) controlled by this probe, to supply, in electrical form, the digital value of the temperature measured analogically by the probe, characterized in that it comprises, associated with the probe (1), a contact controller (Co) for check that the probe (I) is in uninterrupted contact with a part of the living body whose temperature it is to measure, for a predetermined period, sufficient for the probe to have time, given its thermal inertia, to effectively take the temperature of this part of the body,  this contact controller (Co) comprising means (Pi) for controlling the transfer of information from the computer (Ca) to at least one receiving member (R).  2. Apparatus according to claim 1, characterized in that it comprises a delay means (16) for authorizing the transfer of information from the computer (Ca) to at least one receiving member (R) only after lapse of a lapse predetermined time of uninterrupted contact of the probe (I) with the above-mentioned part of the body.  3. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises a contact detector (3, 6) of the probe (1) with the aforesaid body which is arranged on the probe and arranged to control the controller contact (Co).  4. Apparatus according to claim 1 or 2, characterized in that it comprises comparator means (ICi) for comparing the temperature measured by the probe (Te), to a stored reference temperature (To) and different from the ambient temperature , these comparator means (HERE) belonging, with the probe itself (2, 63), to the contact controller.  5. Apparatus according to claim 1 or 2, characterized in that it comprises comparator means (65) for comparing between them two to two temperatures measured successively by the probe (Ti; Ti-1), these comparator means (65 ) belonging, with the probe itself (1), to the contact controller.  6. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises two neighboring electrical contacts (5, 7), isolated from each other and arranged on the surface of the probe (1), in the region of the measuring part (2) of the probe, so that the contact of this part with the body (29) above establishes an electrical connection between these contacts (5, 7).  7. Apparatus according to claim 6, characterized in that the two aforesaid contacts (5, 7) are in an electrical circuit comprising a voltage source (11) connected to a logic circuit (30) whose state is a function of voltage across its terminals, in series with this source and a resistor (31) of high value, this circuit thus being closed only when the probe is in contact with the aforementioned body.  8. Apparatus according to claim I or 2, characterized in that the contact controller comprises, arranged in the region of the measurement part (2) of the probe (la), an electric capacitor part (32, 33) disposed in a capacitive circuit (35) and comprising an armature (32) covered with an insulating layer (33) intended to make contact with the above-mentioned body (29) at the same time as the probe (la), this body (29) forming then the other armature of the capacitor, so that the variation in total capacity of the circuit is modified when the probe (la) is in contact with the above-mentioned part (29) of the body.  9. Apparatus according to claim I or 2, characterized in that the contact controller comprises two neighboring electrodes (45, 46), of different chemical nature, arranged on the surface of the probe, in the region of its measurement part ( 2), these electrodes being arranged in a control circuit (FIG. 4) which comprises means for amplifying (50) the voltage of electrochemical origin appearing between these electrodes when they are brought into contact with a wet part, forming electrolyte, of the aforementioned body, and which further comprises a logic element (55) whose state varies in response to variations in this voltage.  10. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises two electrical contacts (60, 61) carried by the probe, arranged close to one another and movable with respect to the other, at least one of these contacts (60, 61) being elastically movable relative to the other, so that a pressure exerted on the aforesaid body by this sensitive part produces the displacement of the mobile part of these contacts and the electrical contacting of these two contacts and the closing of a control circuit. he. Apparatus according to claim 5, characterized in that the contact controller is arranged to authorize the transfer of information from the computer to the receiver when the first of these temperatures is at least equal to the second (fig. 6).  12. Apparatus according to claim 1 or 2, characterized in that the contact controller comprises comparator means reacting when the temperature measured by the probe passes from a practically stationary value to a higher value (fig. 9).  13. Apparatus according to claim 5, arranged to perform cyclically several preliminary temperature measurements, before an actual temperature measurement, and to store the successive digital values of these preliminary measurements, characterized in that it comprises a counter (72 ) arranged to be incremented when two successive preliminary values (Tj; Tm) are equal, and to be reset to zero when they are different, means (74, 75) interrupting the storage of said values when the content of the counter (72) reaches a predetermined value, the last memorized value (Tm) then constituting the actual measured value.  14. Apparatus according to claim 1, wherein the computer (Ca) is arranged to periodically generate a digital signal whose value varies with the temperature measured by the probe, characterized in that the contact controller is arranged to control the transfer of successive digital values of said signal to at least one receiving member, for example a memory and / or a digital display means, in response to the detection of contact between the probe and the above-mentioned body (FIG. 6).  15. Apparatus according to claim 14, characterized in that the contact controller comprises a circuit (65; IC1) arranged to periodically compare, in pairs, the successive values of said digital signal (Ti; Ti-l) representative of the temperature measured by the probe (2), and produce said transfer when the difference between these successive values goes from zero to a positive value.  Various types of electronic thermometers are known, comprising a thermometric probe intended to be brought into contact with a body whose temperature is to be measured. However, these known thermometers have the disadvantage of requiring the user to keep the probe in contact with the body in question for a sufficient time. If keeping the probe in contact with said body is too short for the measurement, the electronic circuits cannot calculate the correct digital value of the temperature to be measured, which can lead to disturbed operation and loss of values of temperatures previously stored and still required.  The present invention aims to provide an apparatus for measuring the temperature in numerical value of a living body, which is free from this drawback, that is to say which only makes correct measurements, and its subject is a apparatus which conforms to claim 1.  The accompanying drawings show, schematically and by way of examples, several embodiments of the temperature measuring device according to the invention.  Fig. I is a diagram of an embodiment of the apparatus illustrating the principle of the invention. ** ATTENTION ** end of the CLMS field may contain start of DESC **.