ITBO20110455A1 - SYSTEM FOR CHECKING POSITION AND / OR DIMENSIONS OF MECHANICAL PARTS - Google Patents

Description

DESCRIPTION

of the patent for Industrial Invention entitled:

â € œSYSTEM TO CHECK THE POSITION AND / OR DIMENSIONS OF MECHANICAL PARTSâ €

TECHNIQUE SECTOR

The present invention relates to a system for controlling the position and / or dimensions of a mechanical part.

In particular, the present invention finds advantageous, but not exclusive, application in numerically controlled machine tools for determining the position and / or dimensions of machined mechanical parts, to which the following description will make explicit reference without thereby losing generality.

ANTERIOR ART

As it is known, a control system for controlling the position and / or measuring the dimensions of a machined mechanical piece includes a probe, which is equipped with a contact sensor and is mounted movably on the machine tool that works , or that has worked, the mechanical piece, and a remote base station, which is fixed to the structure of the machine tool and receives from the mobile probe radiofrequency or infrared signals that incorporate information relating to the position and / or dimensions of the piece mechanical or at the exact moment in time in which the mobile probe touches the mechanical piece. Normally, the probe is battery powered and therefore its electrical consumption is a crucial factor in determining the commercial success of the control and measurement system.

The infrared versions have enjoyed greater commercial success as the propagation modes favor the isolation of systems that are not in sight, contrary to what happens for radio frequency signals. Furthermore, the installation of infrared control systems does not normally have to meet strict requirements of electromagnetic compatibility, which require very onerous approval procedures.

In infrared measurement and control systems, the probe is equipped with an infrared transmitter, for example at least one infrared LED, and the base station is equipped with at least one infrared receiver, for example an infrared photodiode . The over-the-air transmission of infrared signals between the probe and the base station can be disturbed by the lighting of the rooms where the machine tool and its control and measurement system are located. In fact, fluorescent lamps and incandescent lamps can emit, in an unpredictable way, spectral components in the infrared.

There are several circuit solutions that allow a certain immunity from optical disturbances. For example, the United States patent number US 7,350,307 B2 describes a control and measurement system in which the base station comprises a comparison circuit, which reconstructs the digital signal by comparing the received optical signal with a suitable threshold, and a generation circuit and threshold control, which is configured to vary the threshold as a function of the peak value of the useful optical signal and as a function of the characteristics of the optical disturbance signals.

However, the solution proposed in US 7,350,307 B2 is not completely immune from optical disturbances in the case of particularly intense use of fluorescent lamps.

There are control and measurement systems in which the probe transmits optical signals consisting of an ON-OFF modulated infrared ray impulsive carrier by the bits of the messages to be transmitted to the base station. In particular, the infrared impulsive carrier is constituted by a series of infrared ray pulses that follow one another with a frequency higher than the frequencies most commonly affected by optical disturbances. The base station receiver comprises a suitable band pass filter centered on the frequency of the impulsive carrier to strongly attenuate the disturbing components outside the filter band. In any case, the techniques that use ON-OFF modulated carriers entail, other things being equal, a higher current consumption and therefore a shorter duration of the probe's battery charge.

DESCRIPTION OF THE INVENTION

The purpose of the present invention is to provide a system for controlling the position and / or the dimensions of a mechanical piece which is free from the drawbacks described above and, at the same time, is easy and economical to produce.

In accordance with the present invention, a system is provided for controlling the position or dimensions of a mechanical piece as defined in the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 is a schematic illustration of a numerically controlled machine tool provided with the control system made according to the dictates of the present invention;

Figure 2 illustrates a detailed block diagram of the probe of the control system of Figure 1;

Figure 3 illustrates a basic electrical diagram of an input band-pass filter of the receiving section of the probe of Figure 2;

Figure 4 illustrates a flow diagram of an algorithm for adjusting the gain of the amplifier means of the receiving section of the probe of Figure 2;

Figure 5 illustrates a detailed block diagram of the base station of the control system of Figure 1;

Figure 6 illustrates a block diagram of the receiving section of the base station of the control system of Figure 1 according to a further embodiment of the invention;

Figure 7 illustrates a basic electrical diagram of a part of the receiving section of Figure 6;

Figure 8 illustrates a more detailed block diagram of a final stage of the receiving section of Figure 6;

- Figures 9 to 12 show a more detailed block diagram of the final stage of the receiving section of Figure 6 according to further embodiments of the invention;

Figure 13 illustrates two examples of waveforms generated by the transmission section of the probe of Figure 2; And

- Figures 14 to 17 show the trend of the waveforms of signals present in the final stage of the receiving section of Figure 6, according to some of the embodiments of Figures 9 to 12.

PREFERRED FORMS OF IMPLEMENTATION OF THE INVENTION

In figure 1, 1 generally indicates, as a whole, a numerically controlled machine tool, with 2 a mechanical piece machined by machine 1 and still positioned on the machine 1 itself and with 3 a control system to control the position and / or the dimensions of the mechanical piece 2. The machine 1 includes its own numerical control unit 4. The control system 3 comprises a probe 6, which is mounted on the machine 1 so that it can move, for example by means of slides 7 , in the area where the mechanical part 2 is located, and a remote base station 8, which is fixed to the base of the machine 1 at a certain distance from the probe 6, is connected to the numerical control unit 4 by means of suitable interface means 5 and is able to communicate, via infrared ray signals, with the probe 6. According to an embodiment not shown, the interface means 5 are integrated in the base station 8.

According to the present invention, the probe 6 is constituted, for example, by a touch detection probe and comprises, in particular, a movable arm provided, at one end, with a feeler 9, a detection device 9a, the which is adapted to generate, as soon as the feeler 9 touches the mechanical piece 2, an appropriate electrical signal, and a mobile transceiver 10 to transmit information relating to the status of the probe 6 to the base station 8 via infrared signals, and receive information control from base station 8 via infrared signals. The probe 6 further comprises a microcontroller 11 connected with the detection device 9a to receive the electrical signal generated by the detection device 9a and with the mobile transceiver 10 to control its operation. The base station 8 comprises a remote transceiver 12 to communicate via infrared rays with the probe 6 and a microcontroller 13 to control the operation of the remote transceiver 12 and to communicate with the numerical control unit 4 through the interface means 5.

The transceivers 10 and 12 exchange, in use, infrared ray signals obtained by modulating an impulsive carrier with suitable binary coded messages. The impulsive carrier is constituted by a series of infrared ray pulses that follow each other with a frequency between 100 kHz and 10 MHz, and in particular between 300 kHz and 600 kHz. The impulsive carrier is modulated in amplitude by the binary messages. Advantageously, the amplitude modulation is an ON-OFF modulation. Furthermore, the frequency of the impulsive carrier can be selected within a set of several values including, for example, 350 kHz, 450 kHz and 570 kHz, in order to define as many communication channels that do not interfere with each other, such as it will be explained better later.

With reference to Figure 2, the mobile transceiver 10 of the probe 6 comprises a receiving section 14, a transmission section 15 and a digital regulator device 16 constituted, for example, by an FPGA (Field Programmable Gate Array) suitably configured to regulate in real time some parameters of the reception 14 and transmission 15 sections. The regulator device 16 is, in turn, controlled by the microcontroller 11.

The receiving section 14 comprises receiving devices with one or more infrared photodiodes 17, in particular four photodiodes 17, which are oriented so as to ensure omnidirectional reception, are connected in parallel with each other and are used in photovoltaic mode. , that is, they are not polarized, and a band-pass filter 18 tunable to the desired frequency of the impulsive carrier, connected immediately downstream of the photodiodes 17. The photodiodes 17 are used in photovoltaic mode to reduce the electrical current consumption of the probe 6, which is It is powered by a battery.

The receiving section 14 also comprises variable gain amplifier means 19 for amplifying the signal supplied by the band-pass filter 18 and providing a corresponding amplified signal VA and a comparison section, which comprises a low-pass filter 20 for filtering the signal. amplified VA and a comparator 21 for squaring the amplified signal VA, i.e. producing a corresponding processed signal, in particular a binary signal VD, based on a comparison between the filtered amplified signal VF and a sum signal VTS consisting of the sum of the amplified signal VA with a reference signal or VTH comparison threshold. The low pass filter 20 is connected to the inverting input of the comparator 21. The introduction of the low pass filter 20 in the comparison section allows to increase the immunity of the binary signal VD with respect to the fluctuations of the mean value of the amplified signal IT GOES. The filtered amplified signal VF essentially represents the average value of the amplified signal VA.

According to a further equivalent embodiment (not shown) of the invention, the comparator 21 has the inverting input connected to a fixed reference potential and the receiving section 14 does not have the low pass filter 20 of Figure 2 and comprises a high pass filter which eliminates the direct component from the amplified signal VA, which is constituted, for example, by a capacitance in series with a resistor and is connected between the output of the amplifier means 19 and the summing node which provides the VTS sum signal.

Always referring to Figure 2, the regulator device 16 receives the binary signal VD, which is still at high frequency, and is configured to reconstruct, starting from the binary signal VD, the base band envelope of the signal received by the probe 6, that is the binary message received and originally transmitted by the base station 8. The techniques for reconstructing the envelope can be many. According to a preferred solution, which gave the best results, the regulator device 16 is configured to implement a low pass filter IIR (Infinite Impulse Response), which is not shown and which receives the binary signal VD, and a comparator hysteresis (not shown) connected to the output of the IIR filter, which receives the filtered binary signal and provides the baseband envelope of the received signal.

The regulator device 16 is configured to regulate the gain of the amplifier means 19 as a function of the binary signal VD. The regulator device 16 is also configured to regulate the VTH threshold as a function of the binary signal VD by means of a DAC (Digital to Analog Converter) 22. Furthermore, the regulator device 16 is configured to regulate the center band frequency of the pass filter. band 18.

The amplifier means 19 comprise a plurality of amplifier stages 23a-23c, which are connected in cascade to each other and each have a constant G gain, and selector means 24, which comprise a plurality of connected selection inputs, each, at the output of one of the amplifier stages 23a-23c. In the example illustrated in Figure 2, the amplifier stages 23a-23c are three and are indicated in succession, starting from the filter 18, with 23a, 23b and 23c. The selector means 24 are configured to be controlled by the regulator device 16 so as to select the output of one of the amplifier stages 23a-23c and then select a different amplification level. The G gain of each 23a-23c amplifier stage is approximately 25 dB so that the amplification level is selectable in a set of values comprising 25 dB, 50 dB and 75 dB.

Figure 3 illustrates a basic electrical diagram of the band-pass filter 18. The band-pass filter 18 comprises a plurality of inductances 25, which are connected in parallel with each other, and a respective plurality of switches 26, each of which is arranged in series with a respective inductance 25. The switches 26 are commanded, in opening and closing, by the regulator device 16 to select the center band frequency of the band-pass filter 18, and then to select the communication channel to be listened to. The inductances 25, when the respective switches 26 are closed, are connected in parallel to the photodiodes 17. The photodiodes 17 have respective capacities which are added together (photodiodes 17 in parallel) giving rise to a not negligible overall capacity in parallel to the inductances 25. The center band frequency can be selected in a set of frequencies defined by at least part of all the possible opening and closing combinations of the switches 26, excluding the combination of all the switches 26 open. The example of implementation of Figure 3, which illustrates two inductances 25, allows you to select three different mid-band frequencies, that is, three different communication channels, by closing only one or the other switch 26 or both switches 26. It is essential that at least one of the inductances 25 is connected in parallel to the photodiodes 17 to offer a low impedance load for the continuous and low frequency components of the electric current generated by the photodiodes 17 in the presence of ambient light. In fact, since the photodiodes 17 are not polarized, if the voltage that forms at their ends were to exceed a few hundred millivolts, the junctions of the photodiodes would be directly polarized and this would cause an unacceptable reduction in their optical sensitivity.

The band pass filter 18 also comprises a fine adjustment circuit 27, which is equipped with one or more varicap diodes, is connected in parallel to the inductances 25 and is controlled by the regulator device 16. The fine adjustment circuit 27 provides an additional adjustable capacity during the calibration phase of the probe 6 by means of the regulator device 16 to compensate the tolerances of the inductances 25 and of the capacities of the photodiodes 17 and to center with better precision the center band frequency on the frequency of the impulsive signal transmitted by the base station 8.

Referring again to Figure 2, the transmission section 15 of the mobile transceiver 10 of the probe 6 comprises one or more infrared LEDs 28, a voltage doubler 29 controlled by the regulator device 16 to double the supply voltage VL of the LEDs, and driving means for the LEDs 30, which comprise a DAC converter controlled by the regulator device 16 and a voltage / current conversion circuit for transforming the driving voltage of the LEDs at the output of the DAC into a driving current for the LEDs 28. driving voltage of the LEDs consists of an impulsive carrier modulated by a binary message to be transmitted to the base station 8. The voltage doubler circuit allows to drive several LEDs 28 connected in series. In particular, the voltage doubler circuit comprises a plurality of capacity banks which for most of the time are connected in parallel to a supply voltage (e.g. 3.6 V) and which are connected in series upon command of the regulator device 16 only when it is necessary to carry out the transmission and have a doubled voltage to be able to drive the LEDs correctly.

The structure of the transmission section 15 allows to dynamically adjust the amplitude of the envelope of the driving voltage of the LEDs, and therefore the intensity of the infrared rays emitted by the LEDs 28, to optimize the electrical power consumption of the probe 6 in the different phases of operation. Furthermore, the structure of the transmission section 15 allows to suitably shape the bits of the binary message that modulate the impulsive carrier, i.e. the envelope of the driving voltage of LEDs, in such a way as to attenuate the spectral components far from the carrier frequency. impulsive that could interfere with other probes of the same type operating simultaneously with different carrier frequencies. Figure 13 illustrates two examples of shaping the envelope of the driving voltage of the LEDs. The envelope indicated with VLq has a rectangular shape while the envelope indicated with VLs is shaped according to a portion of a sinusoid. The VLs envelope has the spectral components on neighboring channels that are more attenuated than the analogous components of the VLq envelope.

Another example of shaping, not shown in the figure, provides for modulating the binary signal with a carrier with lower harmonic distortion, for example of a sinusoidal shape. With this expedient the spectral components at multiple frequencies of the carrier and therefore the interference on relatively distant channels are reduced.

Again with reference to figure 2, the probe 6 comprises a power supply unit 32 equipped with an electric battery and a switching-mode power supply (â € œswitching-mode power supplyâ €) to power all the electrical and electronic components of the probe 6. regulator device 16, following the instructions of the microcontroller 11, can disable the power supply unit 32 leaving the probe 6 to work for a limited period of time by exploiting only the charge of the electrical filtering and leveling capacities of the power supply unit 32. operating mode It is useful during the reception phase to reduce the electromagnetic disturbances produced by the switching power supply on the reception circuits and therefore improve the performance of the probe 6.

Finally, the probe 6 comprises acoustic and / or visual signaling devices 33 controlled by the microcontroller 11 to provide information on the status of the probe 6 to the operator of the machine tool 1.

As previously mentioned, the regulator device 16 is configured to adjust the gain of the half-amplifiers 19 and the threshold VTH as a function of the binary signal VD, in order to compensate for the great variability of the intensity of the received signals and power, therefore, optimally reconstruct the base band envelope of the signal received by probe 6, ie the binary message received. These two adjustments take place according to respective algorithms, described below.

With reference to Figure 4, which illustrates a flow diagram of the algorithm relating to the adjustment of the gain of the amplifier means 19, first of all the threshold VTH is set at a suitable initial value V1 (block 100 of Figure 4) and is selected the output of the first amplifier stage 23a (block 101). The V1 value is defined as follows. The amplified signal VA oscillates in a substantially symmetrical way around its average value, which is represented by the filtered amplified signal VF, and has a peak value, with respect to the average value, limited to a VAM value equal to less than half the voltage of powering the amplifier stages 23a-23c.

The V1 value is approximately equal to the VAM value divided by the typical gain of amplifier stages 23a-23c. For example, with a supply voltage of 3 V, a typical gain of 25 dB, and a VAM value of 1.25 V, the V1 value is approximately equal to 75 mV. In this way, when the peak value of the signal at the output of one of the amplifier stages 23a-23b is greater than the value V1, the subsequent amplifier stage 23b-23c is saturated and therefore must not be used. This condition occurs for values of the amplified signal VA lower than its average value and produces values of the sum signal VTS lower than the corresponding values of the filtered amplified signal VF, and therefore low-level pulses of the binary signal VD. In the event that the aforementioned condition does not occur, the binary signal VD remains constantly at a high level. Therefore, if the binary signal VD does not remain constantly at a high level, that is, it has pulses at a low level, which means that the peak value of the amplified signal VA is greater than the threshold VTH (output NO of block 102), then the selection of the first amplifier stage 23a is correct and the algorithm ends; otherwise (output SI of block 102) the output of the second amplifier stage 23b (block 103) is selected. The same check is made on the binary signal VD (block 104) and if it is negative (NO output of block 104), then the selection of the second amplifier stage 23b is correct and the algorithm ends; otherwise (output SI of block 104) the output of the third amplifier stage 23c is selected (block 105) and then the algorithm ends.

The algorithm of figure 4 refers to the example of three amplifier stages 23a-23c. It is obvious that in the case of more than three amplifier stages the final part of the algorithm must be replicated for each additional stage.

Once the gain adjustment of the half-amplifiers 19 has been completed, the VTH threshold is adjusted, which takes place according to the algorithm described below, in order to find an optimal value of the VTH threshold. Initially, the VTH threshold is set at a value equal to half of an interval defined by the maximum allowed dynamics of the amplified signal VA, that is, half of the VAM value, in order to define an upper and a lower sub-interval. If the sum signal VTS has values lower than the corresponding values of the filtered amplified signal VF, which means that the peak value of the amplified signal VA is greater than the VTH threshold, then the VTH threshold is fixed at a new value corresponding to the center of the upper subrange; otherwise the VTH threshold is set at a new value corresponding to the center of the lower sub-interval. This procedure is iterated until the VTH threshold is close enough, less than the resolution of the DAC 22, to the peak value of the amplified VA signal. The VTH threshold value to be used for the reconstruction of the envelope of the received signal is placed at the half of the detected peak value.

The procedures for adjusting the gain of the amplifier means 19 and of the comparison threshold VTH presuppose that the optical signal is always present in reception at the probe 6. For this reason the base station 8 transmits, before each message, a preamble of sufficient duration, in in such a way that the probe 6 can calibrate its receiving section 14 in a substantially continuous manner, that is to say, adjust the gain of the amplifier means 19 and the comparison threshold VTH to optimal values. In this way, probe 6 can adjust its optical sensitivity to the actual quality of the optical channel. Furthermore, the microcontroller 11 can use the adjustments of the reception section 14 made during the preamble to make an estimate of the quality of the optical channel, the estimate being used to regulate the power supply of the transmission section, in particular the driving voltage of the Transmission LED. Therefore, in the presence of a particularly robust optical channel, for example when the probe 6 is very close to the base station 8 or in any case it is in the direction of excellent optical visibility, the transmission section 15 can decrease the electric current to be fed to the LED 28 to reduce the intensity of the infrared rays transmitted, and therefore allow the probe 6 to save electrical power.

With reference to Figure 5, the remote transceiver 12 of the base station 8 comprises a receiving section 34 and a transmission section 35. The receiving sections 34 and transmission 35 have a substantially digital structure and communicate directly with the microcontroller 13 of the base station 8. In particular, as illustrated by the example of Figure 5, the remote transceiver 12 comprises a digital integrated circuit, in particular an FPGA (Field Programmable Gate Array) device 36 which implements part of the functional blocks of both reception sections 34 and transmission 35.

The base station 8 also comprises a power supply unit 37 which can be connected to an external power supply, for example the electrical network or to the on-board power supply from the machine 1, to power all the electrical and electronic components of the base station 8.

The power supply voltages that can be found in the different applications are the most disparate and in some cases prevent the receiver chassis from being connected to the electronics ground reference. This situation is particularly deleterious for the susceptibility to electrical disturbances that follows, as the inevitable parasitic capacities between chassis and electronic circuits inject disturbances into the latter, when they consist of rapid variations in the potential difference between chassis and ground reference. of electronic circuits. The power supply unit 37 comprises an isolated converter, in particular a flyback DC / DC converter equipped with an electronic control unit capable of supplying the necessary different power supply voltages to the electronic components of the base station 8. The flyback DC / DC converter allows to electrically isolate the on-board power supply of the machine 1 from all the electronic components of the base station 8; It is thus possible to connect the base station chassis 8 directly to the electronics ground. In this way, the potential difference between the external metal frame of the base station 8 and the electronic components is stably canceled and therefore the electrical disturbances induced on the electronic components by the parasitic capacities between the metal frame and the components are drastically reduced.

The transmission section 35 comprises one or more infrared LEDs 38, a transmission block 40, which receives, from the microcontroller 13, a message to be transmitted over the air to the probe 6 and transforms this message into a corresponding digital control signal of the LED, a DAC converter 39 controlled by the drive block 40 to provide a driving voltage for the LEDs and a LED driving means 39a, which includes a voltage / current conversion circuit for transforming the driving voltage into a driving current for the LED 38. The transmission block 40 is implemented in the FPGA device 36. Unlike the probe 6, the transmission section 35 does not include any voltage doubler circuit since, thanks to the power supply unit 37 connected to the external power supply, Ã A sufficiently high supply voltage for the LEDs is available. Apart from this difference, the structure of the transmission section 35 is similar to that of the transmission section 15 of the probe 6 illustrated in Figure 2, to allow dynamically adjusting the amplitude of the envelope of the driving voltage of the LEDs at purpose of optimizing the electrical power consumption of the base station 8 in the various phases of operation and attenuating the spectral components far from the carrier frequency.

The receiving section 34 comprises receiving devices with one or more infrared photodiodes 41, which are connected in parallel with each other and inversely biased, and processing means with amplifier means 42 for amplifying the signal provided by the photodiodes 41 and providing a received amplified signal VAB and a conversion and filtering unit 43 connected to the output of the amplifier means 42 to supply a corresponding digital amplified signal VDB encoded with a large number of bits, for example 24 bits. The conversion and filtering unit 43 consists of an integrated component which comprises, in cascade, a sigma-delta ADC converter 44 and a band-pass filter 45 tunable to the desired frequency of the impulsive carrier. The sigma-delta converter 44 has a digital output coded with a high number of bits and the band pass filter 45 is a FIR (Finite Impulse Response) filter. According to the example shown in Figure 5, the output of the sigma-delta converter 44 is encoded at 24 bits and the band pass filter 45 is a 95th order filter (96 taps). The response of the band pass filter 45 is configurable by changing the value of the filter coefficients. The selection of the frequency of the impulsive carrier, and therefore of the communication channel between the base station 8 and the probe 6, can be carried out by writing the internal registers of the band pass filter 45. In particular, the FPGA device 36 is suitable for tune the band pass filter 45 to the desired communication channel on command of the microcontroller 13.

The receiving section 34 further comprises a rectifier block 46, which is connected to the output of the conversion and filtering unit 43 to rectify the digital signal VDB by means of an absolute value operation and provide a corresponding rectified signal VRB, a low pass filter 47, which consists, for example, of an IIR filter connected to the output of the rectifier block 46 to supply a corresponding rectified filtered signal VFB, a threshold generator block 48 to calculate a comparison threshold VTB as a function of the filtered rectified signal VFB, and a comparator block 49 to determine, as a function of the comparison between the filtered rectified signal VFB and the threshold VTB, an output signal corresponding to the baseband envelope of the signal received from the base station 8 , that is, the received signal purified by the impulsive flow rate. The baseband envelope supplied by the comparator block 49, or output signal, is indicated, in Figure 5, with VIB. The reception section 34 finally comprises a reception block 50 for transforming the envelope in baseband VIB into a corresponding received binary message MSG, which is communicated to the microcontroller 13. In particular, the block 50 comprises registers, which are read by the microcontroller 13, and implements one or more algorithms to write the received binary message MSG on these registers and verify its validity. The rectifier block 46, the low pass filter 47, the threshold generator block 48, the comparator block 49 and the receive block 50 are implemented in the FPGA device 36.

The threshold generator block 48 implements, and therefore includes, a peak detector (not shown) with rise times shorter than the fall times to generate a peak-tracking signal of the filtered rectified signal VFB and an attenuator block ( not shown) to generate the VTB threshold by reducing the amplitude of this peak signal by approximately 50%. The VTB threshold thus obtained tracks the peak of the rectified filtered VFB signal, and therefore adapts to the power of the optical signal received by the receiving section 34.

According to a further embodiment of the invention, the infrared ray impulsive carrier transmitted for the exchange of messages between the probe 6 and the base station 8 is modulated in frequency by binary messages. For example, each logic high bit corresponds to a frequency of 450 kHz and each logic low bit corresponds to a frequency of 100 kHz. In the case of several communication channels, the frequency of the impulsive carrier for the transmission of a bit at a high logic level can be selected within a set of several values including, for example, 350 kHz, 450 kHz and 570 kHz, while to each bit at low logic level corresponds the frequency of 100 kHz. This embodiment differs from those illustrated in Figures 2 and 5 essentially in the operating logic of the part of the FPGA device which generates the driving voltage of the LEDs.

According to a further embodiment of the invention, the transmitted infrared ray impulsive carrier is modulated in phase, for example by associating a phase shift equal to 0 ° of the impulse carrier to each bit at a high logic level and a phase shift equal to 180 ° to each bit at a low logic level.

According to a further aspect of the invention, a communication protocol is provided between the probe 6 and the base station 8, ie a method for communicating messages between the probe 6 and the base station 8.

The communication protocol provides an initial phase of programming the probe 6, which includes the bidirectional and non-simultaneous exchange of messages between the base station 8 and the probe 6 in order to configure a series of parameters of the probe 6, for example the frequency of the communication channel, a sleep timer, etc.

At the end of the programming phase, the probe 6 goes into a standby state (â € œstandby stateâ €), in which it periodically transmits a beacon signal (â € œbeacon signalâ €) to signal to the base station 8 its availability for activation.

The base station 8, when it decides to activate the probe 6, responds to the beacon signal by sending an activation confirmation message (â € œactivation acknowledgeâ €). The probe 6 in turn responds by transmitting an identification message containing the identification of the probe 6. At this point, the base station 8 orders the probe 6 to switch to the cycle state (â € œoperating stateâ €), transmitting an appropriate cycle command message, and listens for messages transmitted by the probe 6.

The messages transmitted by the probe 6 in the cycle state include status messages and change messages. The status messages include information on the status of the detection device 9a and / or information on the status of the battery of the power supply unit 32. In particular, in the absence of touch between the feeler 9 and the mechanical part 2, the probe periodically transmits messages of status, alternating, for example, four successive probe status messages with a battery status message. The base station 8, immediately after receiving a battery status message, transmits an acknowledgment of receipt message. On the other hand, when touch and detachment events occur, i.e. when the feeler 9 begins to touch the mechanical piece 2 and, respectively, stops touching the mechanical piece 2, the probe 6 transmits, as soon as possible, or in any case with a repeatable delay, a sequence of two change messages. The base station 8, immediately after receiving the two change messages, transmits the information to the numerical control unit 4. The delays with which the change messages are repeated can be differentiated according to the communication channel (impulsive carrier) used. This expedient allows to minimize the probability that several variation messages are transmitted simultaneously by different probes 6 operating simultaneously with different impulsive carriers. In fact, the collision of variation messages transmitted by several probes 6 could cause serious malfunctions in particularly unfavorable cases, for example when the useful signal is received very weakly and interfering signals on adjacent channels are received with high intensity.

Furthermore, as previously mentioned, the communication protocol between the probe 6 and the base station 8 provides that the base station 8 transmits, immediately before each message, a respective preamble of sufficient duration such that the probe 6 can calibrate its receiving section 14.

Figure 6 illustrates the receiving section of the remote transceiver 12 of the base station 8 according to a further embodiment of the invention, in which the corresponding elements are indicated with the same numbers and abbreviations of Figure 5. According to this embodiment, the receiving section of the remote transceiver 12 has a substantially analog structure and comprises processing means with a receiver stage 51 of the homodyne type, i.e. of the frequency conversion type, connected to the output of the receiving devices, in particular of the means amplifiers 42, to supply the rectified filtered VFB signal representing a processed input signal, and a digital pulse shaper stage 52 connected to the output of the receiver stage 51 to provide the VIB baseband envelope of the signal received by the base station 8.

With reference to Figure 6, the receiver stage 51 of the frequency conversion type comprises a local oscillator 53 for generating a first reference signal VO1 having nominally the same frequency as the impulsive carrier of the received signal, a phase shifter 54 fed by the oscillator 53 to generate a second reference signal VO2 in quadrature with the other reference signal VO1, two non-linear mixers 55 consisting, for example, of respective multipliers to separately mix each of the reference signals VO1 and VO2 with the amplified received signal VAB and two identical low pass filters 56 each connected to the output of a respective mixer 55 to supply two respective baseband signals VBB1 and VBB2. The amplitude of the VBB1 and VBB2 signals is proportional to the product of the base band envelope of the received signal multiplied by the sine and, respectively, the cosine of the same quantity, which is a function of the inevitable difference in frequency and phase between the impulsive carrier of the received signal and the reference signal VO1, since they are not synchronized with each other.

The receiver stage 51 further comprises a detector circuit 57, which receives the two signals VBB1 and VBB2 and supplies the filtered rectified signal VFB. The receiver stage 51 allows precise tuning on the various impulsive carriers without having to modify the parameters of the filters, thanks to the use of the local oscillator 53, whose frequency can be programmed with precision by logic. At the same time, the receiver stage 51 is a simpler and cheaper solution than the digital one of Figure 5. In fact, the reference signal VO1 is already available, because it is used by the transmission section of the base station 8 to generate the signals to be transmitted to the probe 6, without the need for further circuit complications for its synthesis. Furthermore, the receiver stage 51 produces a band-pass filtering centered on the impulsive carrier with performances equivalent to those of the digital solution of Figure 5, although using low-pass filters 56 of a not particularly high order compared to the complexity of the band-pass filter 45 of Fig. 5.

Figure 7 illustrates the basic circuit diagram of the detector circuit 57, which comprises two full-wave active rectifiers 58, which respectively receive the signals VBB1 and VBB2 and have their outputs connected, by means of two respective resistors 59 identical to each other, to single output terminal 60 for providing the VFB filtered rectified signal.

Each active rectifier 58 comprises a respective operational amplifier configured as an inverting half-wave rectifier, indicated with 61, and a respective operational amplifier configured as a non-inverting half-wave rectifier, indicated with 62. Each half-wave rectifier 61, 62 comprises a respective first diode 63a , 64a connected in feedback to the respective operational amplifier 61a, 62a, i.e. connected with the anode and cathode respectively to the inverting input and output of the operational amplifier 61a, 62a, and a second diode 63b, 64b connected at the output to the respective operational amplifier 61a, 62a, i.e. connected with the anode and cathode respectively to the output of the operational amplifier 61a, 62a and to the relative resistance 59. Each inverting half-wave rectifier 61 comprises a first resistor 65a connected in series to the inverting input of the respective operational amplifier 61a and one second resistance 65b connected in feedback to the respective operational amplifier 61a, and in particular between the inverting input of the operational amplifier 61a and the cathode of the related diode 63b. Resistors 65a and 65b have the same ohmic value R1.

Each non-inverting half-wave rectifier 62 comprises a respective resistor 66 connected in feedback to the respective operational amplifier 62a, and in particular between the inverting input of the operational amplifier 62a and the cathode of the relative diode 64b. The resistors 66 have a much greater R2 value than the R1 value, for example greater than or equal to R1 * 10. Advantageously, the value of R2 is equal to R1 * 100. The resistors 59 have an ohmic value equal to R1 / 2: it can be shown that this condition optimizes the performance of the circuit.

The detector circuit 57 described above is a simpler circuit solution than the known theoretical one, which would consist in extracting the square root of the sum of the squares of the signals VBB1 and VBB2 and which would therefore be expensive also as a consequence of the considerable variability of the € ™ intensity of the signals received. The negative aspect of the circuit simplification is that the rectified filtered signal VFB supplied by the detector circuit 57 is affected by a residual oscillation which has an amplitude approximately equal to 8% of the overall amplitude of the signal itself and a frequency equal to eight times the frequency difference between the pulse carrier of the received signal and the reference signal VO1. However, the residual oscillation is tolerable in exchange for the simplicity of the detector circuit 57, thanks also to the presence of the subsequent digital pulse forming stage 52.

Figure 8 illustrates a block diagram of the pulse shaper stage 52, which comprises an amplifier 67, of the inverting type, with a high input impedance (so as not to disturb the operation of the previous detector circuit 57) and with a frequency response of the type high pass to amplify the filtered rectified VFB signal and provide a corresponding VFAB amplified signal which also represents a processed input signal, a control section with a threshold generation and control block 68 to generate and control, as a function of the amplified signal VFAB , a reference signal or comparison threshold VTHB, and a comparison section, or comparator block 69 to determine the baseband envelope, or output signal, VIB based on a comparison between the amplified signal VFAB and the threshold of VTHB comparison. As an alternative to the amplified signal VFAB, and with an appropriate dimensioning of the detector circuit 57 and / or of the circuits of the threshold generation and control block 68, the filtered rectified signal VFB can be directly sent to the input of the comparison section 69 and of the generation and threshold control block 68.

The threshold generation and control block 68 comprises a threshold generator circuit 72 and circuits 70, 71 for automatic control of the difference in amplitude between the processed input signals VFB or VFAB and the reference signal VTHB, in particular a detector circuit 70 to generate, as a function of the amplified signal VFAB, a signal VU indicative of the peak of the amplified signal VFAB, and a discriminator circuit 71 to generate, as a function of the amplified signal VFAB, a signal VN indicative of the noise superimposed on the useful signal transmitted by the probe 6 The threshold generator circuit 72 generates the threshold VTHB, and modifies it dynamically and temporarily, as a function of the signals VU and VN. The threshold generation and control block 68 also comprises a programmable module 73 for storing information relating to the particular application in which the control system 3 is used. The threshold generator circuit 72 determines the comparison threshold VTHB also as a function of the information contained in the programmable module 73. The circuits 70, 71, 72 and module 73 perform an automatic control of the reception sensitivity of the remote transceiver 12, automatically reducing its reception sensitivity based on the characteristics of the processed input signal VFAB (or VFB) , in particular by automatically adjusting the VTHB comparison threshold.

The comparator block 69, the circuits 70, 71, 72 and the module 73 are of a type similar to those described in US patent 7,350,307 B2 of the same applicant. However, the present invention differs from the solution described in US patent 7,350,307 B2 in that the squaring stage 52 comprises a circuit 74 for inhibiting the application of the VFAB signal to the discriminator circuit 71 when the VIB output of the comparator block 69 is ̈ at a high logic level, that is when the amplified VFAB signal exceeds the VTHB threshold in absolute value. The circuit 74 comprises an analogue transmission gate, with logic command, schematized, in the figure, by a controlled switch, which has a first input receiving the signal VFAB, a second input receiving the output signal of the comparator block 69 (VIB) and an output which supplies the corresponding result to the discriminator circuit 71, ie it supplies the signal VFAB only when the output of the comparator block 69 is at a low logic level.

The purpose of the circuit 74, or inhibitor circuit, is to inhibit the effect of the discriminator circuit 71 on the control of the VTHB threshold on the basis of characteristics of the output signal, in particular in the presence of the useful signal. In fact, to improve the immunity to disturbances, the band of the useful signal transmitted, in this case by the probe 6, must be rather narrow around the impulse carrier to allow the low pass filters 56 of the receiver stage 51 to eliminate the disturbing signals. . Since the bandwidth of the useful signal is inversely proportional to the duration of the pulse packets that correspond to a bit of the binary messages (useful signal), then the duration of the pulse packets cannot necessarily fall below a certain value. Therefore, the length of the bits of the binary messages in the case of using an impulsive carrier must be greater than that of the binary messages in the absence of an impulsive carrier. The greater length of the bits would cause the automatic sensitivity control part generated by the discriminator circuit 71 to act, even in the absence of disturbances, thus causing an undesired, albeit slight, reduction in sensitivity. Hence the need to inhibit the discriminator circuit 71 in the presence of the useful signal, to optimize performance.

Figure 9 illustrates a further embodiment of the pulse forming stage 52, which comprises a phase inverter 112, which generates the inverted filtered rectified signal VFBN, drawn here for reasons of congruence with the signals of the other figures, but whose function can be obtained simply by inverting the polarity of all the diodes of the detector circuit 57, a high pass filter 75 consisting, for example, of a capacitance in series with a resistor, to attenuate the low frequency components of the disturbances, an amplifier stage with variable gain 76, at whose output the VFAB signal is available, a non-linear amplifier stage 77 connected to the output of the amplifier stage 76 to amplify the less intense signals and compress the more intense signals, a comparison section with a comparator with hysteresis 78 to determine the envelope in base band VIB on the basis of the comparison between an input signal processed VAN generates from the non-linear amplifier stage 77 and a fixed comparison threshold VTH1 representing reference signals, and a control section with a control circuit 79 for generating, as a function of the signal VAN, a control signal VC adapted to control the gain of the amplifier stage 76. The comparison threshold VTH1 consists of a direct voltage source having the negative terminal connected to the non-inverting input of the comparator 78 and the positive terminal connected to ground. The comparator 78 has a hysteresis width equal to some tens of millivolts and equal to approximately double the absolute value of the threshold voltage VTH1. The non-linear amplifier stage 77 amplifies the small signals so that they become sufficiently greater than the offset errors of the subsequent comparators and compresses the more intense signals to avoid problems due to their own saturation. It comprises an operational amplifier 101 configured as an inverting amplifier, in which the signal is applied through the resistor 105, connected between the output of the operational amplifier 80 and the inverting input of the operational amplifier 101, whose network feedback comprises three branches connected in parallel: the first branch comprises a resistor 102; the second branch comprises a diode 103 with the anode and cathode connected respectively to the output and to the inverting input of the operational amplifier 101; and the third branch comprises a diode 104 and a resistor 106 connected in series with each other. In particular, the diode 104 has the cathode connected to the output of the operational amplifier 101 and the anode connected to a terminal of the resistor 106. The feedback network also comprises a resistor 107 in series with a capacitance 108 connected between the anode of diode 104 and ground.

The operation of the pulse-forming stage 52 of Figure 9 is described below, with reference to the waveforms of Figures 14 and 15, relating respectively to the situations of weak and strong received useful signal. In use, the inverted filtered rectified signal VFBN presents a series of pulses of negative polarity, each followed by a respective tail of decreasing (transient) amplitude oscillations, which are undesirable and unavoidable, as they are due to the rather steep filtering carried out by the low pass filters 56 of the receiver stage 51 (Figure 6). High Pass Filter 75 filters the VFBN signal to remove any low frequency noise components. The high pass filter transforms each pulse of the VFBN signal into two consecutive pulses of opposite polarity, followed by its tail of oscillations.

When the VFB signal has a sufficiently small amplitude, i.e. such as not to conduct the diodes 103 and 104 into conduction, the amplifier stage 77 linearly amplifies the VFAB signal, with an amplification factor equal to the ratio between the resistors 102 and 105, and it inverts its phase, therefore the VAN signal takes the form of two consecutive pulses, the first of negative polarity and the second of positive polarity, followed by the relative tails of transient oscillations. This amplification factor is such as to make the smallest receivable amplitude values of the VFB signal sufficiently greater than the offset errors of comparators 78 and 86, so that the latter can function optimally. Under these conditions, comparator 78 correctly reconstructs the envelope in the VIB base band without the tails of oscillations of decreasing amplitude being able to make it switch, thus generating unwanted pulses.

As the amplitude values of the VFB signal increase, the diode 104 becomes conductive in correspondence with the positive peaks of VFAB and closes the third branch of the feedback network through the resistance 106, thus causing a reduction in the amplification factor. For example, the amplification factor is divided by ten. This allows to prevent possible problems due to a sudden saturation of the operational amplifier 101. Furthermore, when the diode 104 goes into conduction, the capacitor 108 is charged, with negative polarity, through the resistor 107 so that, once the € ™ useful pulse of the VFB signal, an appropriate current absorbed by the capacitor 108 during its discharge is extracted for a certain time from the inverting input of the operational amplifier 101, with the result of causing it to move towards higher potentials the level of the VAN signal for a certain period of time, during which the transient queues of the VFB signal are present. However, as soon as the potential of the VAN signal reaches the threshold voltage of the diode 103, the latter enters into conduction causing a strong reduction, and in particular a substantial zeroing, of the amplification factor of the amplifier stage 77, and therefore preventing further increases in the VAN signal. The oscillation tails following each pulse of the VFB signal are therefore practically suppressed. Also in this case, comparator 78 correctly reconstructs the envelope in the VIB base band without the oscillation tails generating unwanted pulses.

The amplifier stage 76 comprises an operational amplifier 80 configured as an inverting amplifier, whose feedback network comprises a resistor 81 connected between the inverting input and the output of the operational amplifier 80 and a connected N-channel FET transistor 82 with the drain and source terminals in parallel with the resistor 81. The operational amplifier 80 is fed with a dual voltage and its non-inverting input is connected to ground. The gate bias network comprises a pair of resistors 83 and 85 of equal ohmic value R. The resistor 83 is connected between the gate of the FET 82 and the non-inverting input, which, as we have said, is connected to ground, and the resistor 85 is connected between the gate of the FET 82 and the output of the operational amplifier 80. The amplifier stage 76 also comprises a current sink 84 connected between the gate of the FET 82 and ground and controlled by the control signal VC. The current sink 84 is adapted to absorb a current I having an intensity which decreases as the amplitude of the control signal VC increases. In particular, the current I is equal to a maximum current I0 when the control signal VC is zero, while it progressively decreases, until it disappears, as the amplitude of the control signal VC increases up to its maximum value. The equality of the ohmic values of the resistors 83 and 85 and the fact that the voltage between the two inputs of the operational amplifier 80 can be considered practically zero mean that the gateâ € "source voltage of the FET 82 has an even component at half of the drainâ € “source voltage and hence the channel resistance of FET 82 is linear, at least in its â € œtriode regionâ €, as could easily be demonstrated. In other words, the ohmic value R and the maximum current I0 are sized in such a way that the following occurs.

When the control signal VC is zero, the maximum current I0 causes a voltage drop across resistors 83 and 85 such as to make the gate-source voltage negative enough to cut off the FET 82. In this situation the variable gain amplifier stage 76 works at its maximum profit. When, on the other hand, the amplitude of the control signal VC increases, the gate potential is progressively increased causing the gradual ignition of the FET 82 and therefore the gradual reduction of its channel resistance. Consequently, there is a gradual reduction of the gain of the amplifier stage 76. As mentioned, the resistor 83, which must be subjected to the potential difference between the gate and the source of the FET, is not connected to the source, but to ground: given that, thanks to the action of the operational amplifier, the source potential can also be considered equal to the ground potential, the gate is driven as expected and avoids injecting part of the control signal on the signal to be elaborate, as it would happen if the resistance were connected to the source of the FET and consequently also to the inverting input of the operational 80.

The control circuit 79 comprises a comparator 86 for determining a pulse signal VP on the basis of the comparison between the signal VAN and a comparison threshold VTH2 equal to a fraction of the threshold VTH1. The VTH2 threshold is determined by a voltage divider 87 powered by VTH1 and has a value of the order, typically, of 1/3 or 1/2 of VTH1. The control circuit 79 comprises a low pass filter 88 for determining a signal VPM indicative of the average value of the pulse signal VP and an amplifier comparator 89 followed by a diode 90 for determining the control signal VC based on a comparison between the signal VPM and a third positive comparison threshold VTH3 connected between the inverting input of the comparator amplifier 89 and ground.

The low pass filter 88 consists, for example, of a one-pole filter having a relatively large time constant with respect to the useful signals. For example, the time constant of the low pass filter 88 is equal to 100 ms. The assembly formed by comparator-amplifier 89, threshold VTH3, diode 90 and current sink 84 is constituted, for example, by a single BJT transistor configured with a common emitter. In this case, the VTH3 threshold is defined by the base-emitter threshold voltage of the BJT transistor.

The control circuit 79 further comprises an inhibitor circuit 91 for inhibiting the contribution to the gain reduction of the amplifier stage 76 of the signals of such amplitude as to make both comparators 78 and 86 switch. The inhibiting circuit 91 comprises an AND gate 92, which has a first input receiving the impulsive signal VP, a second input negated, through a NOT gate 93, receiving the output signal of the comparator with hysteresis 78 (VIB) and an output that provides the corresponding logic result to the low pass filter 88 The logic gates 92 and 93 consist, for example, of simple bipolar transient stages suitably configured. The operation of circuit 79 is also based on the fact that the useful signal has a much lower dutyâ € “cycle (for example, about 1%) than that of the noise background and therefore its contribution to the duty-cycle of the VP signal will be modest in relation to that of disorders. Furthermore, the inhibitor circuit 91 ensures that the useful signal, if sufficiently intense to cause the comparator 78 to switch, does not provide any contribution to the reduction of optical sensitivity, and that the disturbing signals, which, due to their amplitude distribution generally irregular, they will have with high probability components of such amplitude as to make the comparator 86 switch, but not the comparator 78, causing the increase of VC and the consequent reduction of the gain of the amplifier 76 up to the point in which the peak amplitude of the VAN signal due to disturbances slightly exceeds VTH2 and therefore does not reach VTH1, thus carrying out a correct automatic control of the optical sensitivity of the base station 8 to optimally adapt to the intensity of the disturbances received and correctly reconstruct the useful signals , obviously if received with sufficient breadth.

Therefore, the control section with the control circuit 79 carries out an automatic sensitivity control by automatically reducing the reception sensitivity on the basis of the characteristics of the processed input signal VAN, in particular by varying the gain of the amplifier stage 76, in which the bottom are not amplified enough to be able to exceed the VTH1 threshold and therefore do not generate spurious logic signals in the VIB base band envelope (comparator output with hysteresis 78). In the absence of the inhibitor circuit 91, which inhibits the automatic sensitivity control based on characteristics of the output signal VIB, also the useful signal could generate a reduction in sensitivity (reduction of the gain of the amplifier stage 76) which, in certain cases in which if the useful signal is received very weakly, it could cause an incorrect reconstruction of the base band envelope of the received signal. However, as we have said, the useful signal normally has a much lower duty-cycle than that of the noise signals, and therefore probably the useful signal would determine a sufficiently small reduction in sensitivity to allow the useful signal itself to exceed the VTH1 threshold and that the baseband envelope of the received signal is reconstructed correctly. Therefore, according to a further not illustrated embodiment of the present invention, the control circuit 79 is devoid of the inhibitor circuit 91 and the pulse signal VP is conducted directly to the low pass filter 88.

According to a further embodiment illustrated, in principle, in Figure 10, in which the corresponding elements are indicated with the same numbers and abbreviations of Figure 9, and in which the non-linear amplifier stage 77 is shown, for simplicity, as a single block, the inhibitor circuit 91 further comprises a resistor 94 connected between the output of the comparator 86 and the input of the low pass filter 88 and a further resistor 95 connected between the output of the AND gate 92 and the input of the low pass filter 88. The ratio between the resistances 94 and 95 is such as to determine only a partial inhibition of the gain reduction of the amplifier stage 76 when the peak amplitude of the VAN signal exceeds VTH1. This partial inhibition makes it possible to avoid that in the presumably rare case of sudden appearance of particular types of disturbing signals, having a sufficiently regular amplitude distribution, i.e. substantially devoid of intermediate amplitude values, and sufficiently large amplitude values high, such as to always switch both comparators 78 and 86, the desired gain reduction does not occur, thus not allowing the correct reconstruction of the base band envelope of the received signal.

According to a further embodiment illustrated in Figure 11, in which the corresponding elements are indicated with the same numbers and abbreviations of Figures 9 and / or Figure 10, the pulse forming stage 52 differs from the embodiment of Figure 10 for the following wait.

The pulse shaper stage 52 has no variable gain amplifier stage 76 of Figure 10 and the high pass filter 75 is connected directly to the input of the non-linear amplifier stage 77. Figures 16 and 17 show the main shapes wave in cases of weak and strong received useful signal respectively. The pulse-forming stage 52 comprises a capacitor 96 connected between the output of the non-linear amplifier stage 77 and the inverting input of the comparator 78, to decouple the continuous signal components between the non-linear amplifier stage 77 and the comparators 78 and 86, and a capacitor 97 connected between the inverting input of comparator 78 and the inverting input of comparator 86. Capacitors 96 and 97 have negligible reactance at the frequency of the VAN signal supplied by the non-linear amplifier stage 77. Consequently , signals VANS1 and VANS2, respectively on the inverting inputs of comparators 78 and 86, contain a component equal to the signal VAN with practically unchanged amplitude. The pulse forming stage 52 also comprises a voltage divider consisting of a resistor 98 connected between the inverting inputs of the comparators 78 and 86 and a resistor 99 connected in series to the resistor 98, between the inverting input of the comparator 86 and mass. In the control section, the control circuit 79 comprises, in place of the current sink 84 of Figure 10, a current source 100, which is connected between the inverting input of the comparator 78 and ground and is controlled by VC control signal to generate an adjustable voltage offset which is added to the VAN signal, thus generating the VANS1 and VANS2 signals. Comparators 78 and 86 have non-inverting inputs connected directly to ground, ie the comparison thresholds VTH1 and VTH2 are both zero.

The current I generated by the current source 100 substantially circulates only in the voltage divider 98, 99, generating a corresponding voltage drop across the voltage divider 98, 99 which loads capacities 96 and 97, since the current I, modulated from the control signal VC, is constant or slowly variable due to the filtering operated by filter 88. The voltage drop across the entire voltage divider 98, 99 defines a first voltage offset VOFF1 which is added to the amplified signal VAN and supplies the VANS1 signal at the inverting input of comparator 78. The voltage drop across resistor 99 defines a second voltage offset VOFF2 which is a fraction of the voltage offset VOFF1 and which is added to the amplified signal VAN, the latter with original amplitude, thanks to the presence of capacitor 97 which opposes negligible reactance, and supplies the VANS2 signal at the inverting input of comparator 86. For example, resistors 98 and 99 have the same ohmic value and, therefore, the voltage offset VOFF2 is equal to half the voltage offset VOFF1.

The greater the current I, the greater the voltage offset VOFF1, and the greater the amplitude of the amplified signal VAN must be to trigger the comparator 78 and generate the VIB signal. In other words, a higher current I corresponds to a lower optical sensitivity of the base station 8. The reduction of optical sensitivity has the purpose of preventing any background noise from causing the generation of spurious signals at the comparator output. 78 and at the same time to allow the useful signals, obviously if of amplitude sufficiently higher than that of the background disturbance, to be correctly reconstructed.

The regulation of the current I is explained below with reference to the extreme case in which the inhibitor circuit 91 has no effect, that is, in the case in which the resistor 94 has a null value (short circuit) and the resistor 95 has an infinite value (circuit open). The VPM signal at the output of the low pass filter 88 is a slowly variable analog signal proportional to the average value of the pulsed signal VP, i.e. proportional to the percentage of time in which the sum of the VAN signal with the voltage offset VOFF2 It is less than the VTH2 threshold (i.e. it is negative). In other words, the VPM signal is proportional to the percentage of time in which the negative peaks of the amplified VAN signal exceed, in absolute value, the voltage offset VOFF2. When the VPM signal exceeds the VTH3 threshold, the feedback loop constituted by the control circuit 79 closes, which adjusts the current source 100 so as to generate the voltage offset VOFF1. The loop gain of the control circuit 79 is of such magnitude that the offset VOFF2 approximates, in absolute value, the absolute value of the negative peaks of the VAN signal and consequently VOFF1 approximates, in absolute value, double the value absolute of the negative peaks of the VAN signal, assuming that the resistances 98 and 99 are equal to each other. In this way, the component of the VAN signal due to the background noise signals does not cause undesired switching of the comparator 78, while the component of the VAN signal due to the useful signal, if sufficiently stronger than that of the background noise, causes the signal to switch correctly. comparator 78 and, thanks to its low duty - cycle, makes a limited contribution to the increase in VC and the consequent reduction in sensitivity.

By using resistors 94 and 95 with finite ohmic values different from zero, the inhibitor circuit 91 has the same effect described for the embodiments of Figures 9 and 10, that is, it allows to reduce the contribution of the signal useful for the reduction of sensitivity and at the same time avoid that the sudden appearance of particular types of disturbance signals, characterized by a particularly regular distribution of amplitude and sufficient intensity to make both comparators 78 and 86 switch, does not produce the necessary reduction in sensitivity.

The embodiment of Figure 11 has the same operation as the embodiments 9 and 10, with the advantage of comprising fewer electronic components, and therefore of allowing to realize a pulse-forming stage 52 of more compact dimensions.

According to a further embodiment illustrated in Figure 12, in which the corresponding elements are indicated with the same numbers and abbreviations as in Figure 9, the inhibitor circuit 91 comprises a further low-pass filter 109 to determine a signal VIBM indicative of, or proportional to, the , average value of the envelope in base band VIB, a further comparator 110 to compare the signal VIBM with a fourth positive comparison threshold VTH4 connected between the non-inverting input of the comparator 110 and ground, and an AND gate 111, the which includes two inputs receiving respectively the envelope in base band VIB and the output signal of the comparator 110 and an output connected to the input of the NOT gate 93. The low pass filter 109 can in some cases advantageously be of the asymmetrical type , that is to have a rise time constant less than the fall time constant. The set formed by comparator 110 and threshold VTH4 is simply constituted by a single transistor BJT configured as a common emitter, and therefore the threshold VTH4 is in itself defined by the base-emitter threshold voltage of the transistor BJT, which is ̈ typically equal to 0.6 V. The logic functions of the network constituted by gates 111, 92 and 93 are performed, for example, by simple suitably configured BJT transistor circuits.

The operation of the pulse shaper stage 52 of Figure 12 is described below. In use, in the presence of the useful signal, which, as is known, has a remarkably small duty - cycle, the VIBM signal does not exceed the VTH4 threshold and, therefore, the output of comparator 110 is at a high logic level and the AND gate 111 â € œopensâ €, thus allowing the envelope in base band VIB, if present, to prevent, by â € œclosingâ € AND gate 92, transmitting the impulsive signal VP to the low pass filter 88, and thus preventing the useful signal from causing an undesired, albeit small, reduction in sensitivity. Any disturbances present, which in general have a fairly irregular amplitude distribution, most likely have amplitude values such as to activate the comparator 86, but not the comparator 78, and therefore cause, thanks also to a suitably large loop gain , the appropriate reduction of sensitivity. If optical disturbances suddenly occur having a particularly regular amplitude distribution and amplitude values high enough to make both comparators 78 and 86 switch, it is very likely that these disturbances have a duty-cycle higher than that of the useful signal and such to bring the output of the comparator 110 to a low logic level. The output of the comparator 110 at low logic level â € œclosesâ € the AND gate 111, and consequently â € œopensâ € the AND gate 92, thus allowing the transmission of the pulse signal VP to the low pass filter 88 and therefore the operation of the automatic sensitivity control. When disturbances with regular distribution of amplitude appear, the envelope in the VIB base band is therefore affected by spurious signals only for a short time interval, which is essentially equal to the sum of the response times of the filter 109 and of the Control circuit loop 79 (typically hundreds of milliseconds). A similar behavior occurs, moreover, also in the embodiments of figs. 10 and 11.

It should be noted that the circuit parameters of the pulse forming stage 52 of Figures 9-12 can be chosen in such a way that, even in the absence of external disturbance signals, the control circuit 79 is always in operation, operated by a control component. background noise of the VAN signal essentially due to the noise generated by the photodiodes 41 and by the amplifier means 42. In this way, the pulse shaper stage 52 always operates with the maximum possible optical sensitivity without having to take into account, with further margins, the variability of the circuit parameters and the noise of the previous stages, also as a function of the different carrier frequency values on which the equipment is tuned.

According to a further, not illustrated embodiment of the invention, the pulse-forming stage 52 has a structure substantially similar to that illustrated in Figure 11 with the difference that the inhibitor circuit 91 is of the type illustrated in Figure 12, i.e. It is devoid of the resistors 94 and 95 (Figure 11) and comprises the filter 109, the comparator 110, the threshold VTH4 and the AND gate 111 (Figure 12).

According to a not illustrated embodiment of the invention, all the electronics of the remote transceiver 12 of the base station 8 are supplied with a non-dual voltage, and therefore all the points that in the embodiments illustrated by figures 7, 9 , 10 and 11 and 12 were connected to ground, they are connected to a fixed reference potential lower than the supply voltage, for example equal to half the supply voltage.

Claims (7)

CLAIMS 1. System for checking position or dimensions of a mechanical part (2), with At least one probe (6) comprising a detection device (9a) and a mobile transceiver (10) with a transmission section (15) connected to the detection device (9a) and able to transmit over the air a signal indicating the state of said at least one probe (6), the signal having an impulsive carrier of known frequency, e A remote transceiver (12) with a receiving section (34) and a transmitting section (35), the receiving section (34) comprising · Receiving devices (41) adapted to receive said signal over the air, e Processing means suitable for processing the received signal to obtain an output signal as a baseband envelope (VIB) of the received signal (VAB), characterized in that said reception (34) and transmission (35) sections have a structure essentially digital. 2. System according to claim 1, with a base station (8) comprising the remote transceiver (12) and a microcontroller (13), said receiving (34) and transmitting (35) sections of the remote transceiver (12) are directly connected to the microcontroller (13). System according to claim 1 or claim 2, in which the remote transceiver (12) comprises a digital integrated circuit (36), said receiving (34) and transmitting (35) sections are substantially made in the digital integrated circuit ( 36). System according to one of the preceding claims, in which the remote transceiver (12) uses digital processing. System according to claim 4, wherein the remote transceiver (12) comprises a FIR filter (45). 6. System for checking position or dimensions of a mechanical part (2), with At least one probe (6) comprising a detection device (9a) and a mobile transceiver (10) with a transmission section (15) connected to the detection device (9a) and able to transmit over the air a signal indicating the state of said at least one probe (6), the signal having an impulsive carrier of known frequency, e A remote base station (8), comprising a remote transceiver (12) with receiving devices (41) suitable for receiving said signal via the air and processing means suitable for processing the received signal to obtain an output signal (VIB), and a power supply unit (37) that can be connected to an external power supply, characterized in that said power supply unit comprises an isolated converter. 7. A system according to claim 6, wherein said isolated converter is a flyback DC / DC converter.