FR2706605A1 - Circuit for processing the output signal of a frequency-signal sensor and corresponding sensor - Google Patents

Abstract

The present invention relates to a circuit for processing the output signal of a frequency-signal sensor, characterised in that it comprises: means (110) for detecting temperature and means (120, 130, 140) capable of reducing the duty ratio of the output signal of the processing circuit when the detected temperature becomes greater than a predetermined threshold.

Description

 The present invention relates to the field of sensors delivering a frequency output signal.

 The present invention finds particular, but not exclusively, application in the field of motor vehicles.

 By "frequency output signal" is meant an electrical signal whose main useful information is represented by the frequency of the signal.

 Many sensors with frequency output signal have already been proposed.

 Generally, these sensors are associated with a shaping circuit which delivers a 1/2 duty cycle signal.

 By "duty cycle" is meant the ratio between the time at the high level of the signal (that is to say the time of current flow generated by the saturation of an output gate) and the period of the signal.

 Such sensors are in particular used on motor vehicles, for example as a speed sensor.

 In particular, speed sensors have been proposed on motor vehicles comprising a toothed wheel driven in rotation and a coil, traversed by a current, influenced by said toothed wheel, or a rotary magnet and a Hall effect probe influenced by this magnet.

 These sensors and associated processing circuits sometimes deliver their output signal to a large number of operating modules.

 For example, in the field of motor vehicles, speed sensors sometimes deliver their output information up to 10 operating modules, such as speed indicators or limiters, on-board computers and computers for navigation, control, attitude of the vehicle ...

 This requires significant output power for the shaping stage.

 Furthermore, these sensors are often placed in a high temperature environment, for example at the outlet of the gearbox.

 The Applicant has found that these processing circuits for these sensors pose a major problem: at high temperature there is a significant risk of faulty operation and loss of information.

 The main object of the present invention is to remedy this drawback.

 In the context of the present invention, this object is achieved by a circuit for processing the output signal of a frequency signal sensor, characterized in that it comprises - temperature detection means, and - suitable means reducing the duty cycle of the output signal from the processing circuit when the detected temperature is above a threshold.

 It is important to note that the structure in accordance with the present invention does not alter the signal frequency or the characteristics of the rising edge and therefore does not modify the subsequent processing or exploitation of these frequency and rising edge.

 Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings given by way of nonlimiting example and in which - FIG. 1 represents a schematic view under form of functional blocks of a processing circuit according to the present invention, - Figure 2 illustrates a particular non-limiting embodiment of a processing circuit according to the present invention, and - Figure 3 shows a timing diagram of the operation of this circuit.

 We see in Figure 1 attached a device comprising a sensor 10, a conventional processing circuit 20 and a processing circuit 100 according to the present invention.

 The sensor 10 can be formed of any conventional sensor with a repetitive rectangular frequency output signal, that is to say as indicated above, any sensor delivering a repetitive rectangular electrical signal whose main useful information is represented by the signal frequency .

 Such a sensor 10 can be formed for example of a toothed wheel of soft magnetic material driven in rotation associated with a magnetically excited coil and influenced by the passage of the teeth of the wheel. The sensor 10 can also be formed for example of a magnet driven in rotation opposite a Hall effect probe.

 The processing circuit 20 is also conventional in itself. It is suitable for shaping the output signal from the sensor 10 and in particular, without modifying the output frequency of the sensor 10, imposing a known generally constant duty cycle. Most often this duty cycle is 1/2. In other words, the majority of the known processing circuits 20 deliver an output signal, referenced "SIGNAL" in the appended FIGS. 1 and 2, the time of which at the high level is equal to half of the period of the signal.

 These processing and shaping circuits 20 being known in themselves to those skilled in the art will not be described in more detail below.

 The processing circuit 100 according to the present invention essentially comprises, as indicated above, means 110 for detecting temperature and means 120, 130, 140 capable of reducing the duty cycle of the output signal of the processing circuit 20 when the temperature detected by the means 110 is greater than a predetermined threshold.

 More precisely still, according to the particular and preferred embodiment represented in the appended FIG. 1, the processing circuit 100 according to the present invention comprises: - a temperature sensor 110, - a multiplexer stage 120, - a monostable 130, and - a synchronization stage 140.

 The output 121 of the multiplexer drives an output stage 150.

 The temperature sensor 110 can be the subject of various variant embodiments.

 The temperature sensor 110 can detect the ambient temperature around the processing circuit 100.

 However, preferably, the output stage comprises a semiconductor power transistor 154, and the temperature sensor 110 is adapted to detect the temperature of this transistor.

 The means for monitoring the temperature of this transistor can be formed for example of a thermal cell diffused on the same substrate as this transistor 154.

 The temperature can also be evaluated by estimating the energy consumed by this transistor using a desaturation voltage and current reading thereon.

 The monostable 130 receives as input, on the one hand the signal from the conventional processing means 20, on the other hand a clock signal referenced HOR.

 The monostable 130 generates on its output 131 a MONO signal synchronized with the output signal of the processing circuit 20. The duty cycle of the MONO signal is much less than 1/2, for example of the order of 1/5. By way of nonlimiting example, the duration of the pulses of the signal MONO, delivered at the same frequency as the output signal of the processing means 20, can be equal to the period of the clock signal HOR.

 The multiplexing stage 120 is controlled by the output of the synchronization stage 140. The purpose of the multiplexing stage 120 is to direct the output stage 150, ie the output signal of the processing means 20, or the MONO signal from the monostable 130.

 The synchronization stage 140 receives on its input 141 the output signal from the processing means 20 and on its input 142 the TEMP signal coming from the temperature sensor 110.

 The synchronization stage 140 delivers on its output 143 a TEMP1 signal which has a first switchover as soon as the TEMP signal applied to its input 142 corresponds to a crossing, for example, of the predetermined temperature threshold. The TEMP1 signal delivered on the output 143 of the synchronization stage 140 has a second tilting synchronized on the signal coming from the processing means 20 when the TEMP signal represents a lowering of temperature below the predetermined threshold.

 As will be understood on reading the description which will follow with regard to FIG. 3, the TEMP1 signal coming from the synchronization stage 140 thus makes it possible to route the MONO signal coming from the monostable 130 to the output stage 150 from the moment of detection of the exceeding of the predetermined temperature threshold, and on the other hand makes it possible to return to the signal from the processing means 20 in synchronism with this signal, when the detected temperature has again fallen below the predetermined threshold.

 The output stage 150 can be the subject of numerous variant embodiments.

 According to the particular embodiment shown in FIG. 1, this output stage 150 comprises an amplifier buffer stage 152, a transistorized power stage 154 and a protection resistor 156.

 The amplifier buffer stage 152 has its input connected to the output 121 of the multiplexer stage 120.

 The transistorized power stage 154 has its control input connected to the output of the buffer stage 152. The protection resistor 156, one terminal of which corresponds to the output of the processing circuit, is connected in series with the main conduction path of the 'power stage 154.

 According to the particular embodiment shown in FIG. 2, the monostable 130 is composed of two flip-flops 132, 133 and an AND gate 134.

 The two flip-flops 132, 133 are of type D.

 The input flip-flop 132 has its input D connected to the output of the processing means 20 delivering the signal.

The clock input CK of flip-flop 132 receives the clock signal HOR.

The input D of the second flip-flop 133 is connected to the output Q of the flip-flop 132. The flip-flop 133 also receives the clock signal on its clock input CK
HOR.

 A first input of the AND gate 134 is connected to the Q output of the first flip-flop 132. The second input of the AND gate 134 is connected to the Q output complemented by the second flip-flop 133.

 The MONO signal at the output 131 of the monostable stage 130 is available on the output of the AND gate 134.

 The synchronization stage 140 shown in FIG. 2 comprises a flip-flop 144 and a NOR gate 145.

 The flip-flop 144 is of type D. It has its input D connected to the output of the temperature sensor 110. The clock input CK of the flip-flop 144 receives the signal from the processing means 20.

 The NOR gate has a first input connected to the output Q of the flip-flop 144 and a second input connected to the output of the temperature sensor 110.

 The TEMP1 signal available on output 143 of synchronization stage 140 is obtained on the output of NOR gate 145.

 The multiplexer stage 120 shown in FIG. 2 comprises an inverter 122, two AND gates with two inputs 124, 126 and an OR gate 128.

 The inverter 122 has its input connected to the output 143 of the synchronization stage 140.

 The AND gate 124 has a first input connected to the output 131 of the monostable 130 and a second input connected to the output of the inverter 122.

 The second AND gate 126 has a first input connected to the output 143 of the synchronization stage 140 and a second input connected to the output of the processing means 20.

 The OR gate 128 has a first input connected to the output of the AND gate 124 and a second input connected to the output of the AND gate 126.

 The output signal SOR available on the output 121 of the multiplexer stage 120 is obtained on the output of the OR gate 128.

Those skilled in the art will readily understand that, depending on the state of the TEMP1 signal originating from the synchronization stage 140, the inverter 122 authorizes, via the AND gates 124, 126, respectively, the transfer of the signal
MONO from the monostable 130 or the signal from the conventional processing means 20 to the OR gate 128.

 The operation of the circuit thus formed is illustrated in the timing diagram of FIG. 3.

 The six lines of the timing diagram of FIG. 3 represent respectively from top to bottom - the clock signal HOR applied to the monostable 130, - the frequency signal with cyclic ratio 1/2 coming from conventional processing means 20, - the signal MONO from the output 131 of the monostable stage 130, - the TEMP signal from the output of the temperature sensor 110, - the TEMP1 signal from the output 143 from the synchronization stage 140, and - the SOR signal from the output 121 of the multiplexer 120 and applied to the output stage 150.

 The clock signal HOR has, of course, a frequency and a constant duty cycle.

 The signal from the processing means 20 shown on the second line of the timing diagram in FIG. 3 also has a constant frequency as well as a constant duty cycle of 1/2. This representation is given only by way of nonlimiting illustration and supposes the delivery at the output of the sensor 10 of an invariant signal, that is to say for example in the case of a speed sensor, a constant speed.

 The MONO signal shown in the third line of Figure 3 is synchronized with the signal from the processing means 20 and has a duty cycle much lower than the latter, typically 1/5 as indicated above.

 The TEMP signal represented on the fourth line of the timing diagram in FIG. 3 represents the crossing of the predetermined temperature threshold.

 More precisely, this TEMP signal is at the low level as long as the detected temperature is below the predetermined threshold, and on the other hand passes to the high level as soon as the detected temperature exceeds the predetermined threshold by excess.

 The signal TEMP1 represented on the fifth line of the timing diagram of FIG. 3 corresponds to the output of the synchronization stage 140.

 As indicated above, this signal TEMP1 changes state as soon as the detected temperature exceeds the predetermined threshold by excess, that is to say as soon as the signal TEMP goes from low level to high level.

 Thus, as can be seen on the sixth line of FIG. 3 and as can be understood on examining the circuit represented in FIG. 2, as soon as the signal TEMP1 switches from high level to low level, which corresponds to crossing by excess of the predetermined temperature threshold, the multiplexer stage 120 switches from the signal from the processing means 20 to the MONO signal from the monostable stage 130. This arrangement allows an immediate reduction in the duty cycle of the signal applied to the stage of output power 150, and therefore allows immediate limitation of the heating thereof.

 On the other hand, as can be seen in FIG. 3, the second switching of the TEMP1 signal is not obtained as soon as the temperature falls below the predetermined threshold, that is to say as soon as the TEMP signal switches from the high level to low level, but only in synchronism with the signal from the processing means 20 after lowering the temperature.

 In other words, the essential operation of the circuit according to the present invention is as follows - as long as the junction temperature of the power stage 154 is normal, that is to say below a predetermined threshold, the output signal of the processing circuit 100 is in complete phase with the phenomenon detected by the sensor 10 and has a duty cycle of 1/2, - however as soon as the detected temperature of the junction becomes higher than a predetermined temperature threshold, the output signal becomes impulse in the form of short high state, for example of duty cycle 0.2 or less to allow the junction to cool and return quickly to the normal mode previously described.

 The operating modules connected to the output of the processing circuit 100 therefore always receive a signal whose frequency is proportional to the variation in the physical phenomenon detected.

 The present invention makes it possible in particular thanks to the reduction in power obtained to reduce the dissipation surface required on the semiconductor substrate and consequently to reduce the volume and the cost of the components of the processing circuit.

 The present invention also makes it possible to improve the reliability of the system.

 The present invention also allows a circuit overheating diagnostic function.

 The present invention can be applied to any sensor whose frequency of the output signal is proportional to the frequency of variation of a phenomenon to be measured. It applies very particularly as indicated above to speed sensors, in particular speed sensors on motor vehicles.

 It should be noted that the signal obtained on the output of the processing circuit 100 described above actually delivers two pieces of information: a first useful item of information corresponding to the phenomenon detected by the sensor 10 and represented by the frequency of this output signal, and a second item of information corresponding to the crossing of the temperature threshold represented by switching in the duty cycle of the signal.

 According to a variant, it is possible to envisage transmitting three pieces of information using the output signal from the processing circuit, by modulating the duty cycle of the signal as a function of an additional parameter, for example the temperature detected by the sensor 110 The three useful pieces of information obtained on the signal are then as follows: the main information corresponding to the phenomenon detected by the sensor 10 represented by the frequency of the output signal, the crossing of the temperature threshold represented by the switching of the signal duty cycle below a threshold and the actual detected temperature represented by the continuous modulation of the duty cycle of the output signal.

 Of course the present invention is not limited to the particular embodiment which has just been described but extends to any variant in accordance with its spirit.

Claims (13)

 1. Circuit for processing the output signal of a frequency signal sensor, characterized in that it comprises - means (110) for temperature detection, and - means (120, 130, 140) capable of reducing the duty cycle of the output signal from the processing circuit when the detected temperature becomes higher than a predetermined threshold.  2. Circuit according to claim 1, characterized in that the detection means (110) detect the ambient temperature.  3. Circuit according to claim 1, characterized in that it comprises an output stage (150) comprising a semiconductor transistor (154) and in that the detection means (110) are adapted to measure the temperature of this transistor.  4. Circuit according to claim 3, characterized in that the temperature detection means (110) comprise a thermal cell diffused on the same semiconductor substrate as the transisitor (154) of the output stage (150).  5. Circuit according to claim 3, characterized in that the temperature detection means (110) are adapted to evaluate the temperature of the transistor (154) on the basis of a current and voltage measurement.  6. Circuit according to one of claims 1 to 5, characterized in that it comprises a multiplexer stage (120), a monostable stage (130) and a synchronization stage (140).  7. Circuit according to claim 6, characterized in that the multiplexer stage (120) is adapted to route to an output stage (150) either the signal from a sensor (10, 20), or the signal from of the monostable stage (130).  8. Circuit according to one of claims 6 or 7, characterized in that the monostable stage (130) delivers a pulse signal at output synchronized with the signal from a sensor (10, 20).  9. Circuit according to one of claims 6 to 8, characterized in that the synchronization stage (140) has a first output tilting as soon as the temperature detection means (110) detect a crossing by exceeding the threshold of predetermined temperature, and on the other hand only exhibits a second switchover in output in synchronism with a signal from a sensor (10, 20) when the detected temperature has again fallen below the predetermined threshold.  10. Circuit according to one of claims 1 to 9, characterized in that the output signal from the processing circuit delivers two pieces of information: a first useful piece of information represented by the frequency of the signal and one piece of information representative of a threshold crossing temperature represented by switching the duty cycle of the signal below a predetermined value.  11. Circuit according to one of claims 1 to 9, characterized in that the output signal from the processing circuit delivers three pieces of information: a first useful item of information represented by the frequency of the useful signal, a second item of information representative of a crossing temperature threshold represented by switching the duty cycle of the signal below a predetermined value, and third useful information represented by the modulation of the duty cycle of the signal.  12. Sensor comprising a transducer sensitive to a physical phenomenon and a processing circuit according to one of claims 1 to 11.  13. Application of the processing circuit and the sensor according to one of claims 1 to 12 on motor vehicles.