FR2473822A1 - Near-field information communication system - has programmable encoder head which influences decoder head via electromagnetic field generated by resonant circuit - Google Patents

Abstract

The device enables transmission, without contact or electrical link, to a separate device having information transmitted to it from a further device, known as dynamic coding. The device allows a programming head (coder), to influence without any electrical connection, a programmable head to write a code, the latter being able to influence, also without electrical connection, the programming head or a read head to reform the written code. Parallel information at the programming head is translated into series information which is transmitted to the programmable head by the opening and closing of a transistor switch controlling a resonant circuit. The programmable head is put into a writing node only when a received code is verified as correct. The resonant circuit comprises a spiral on a p.c.b. and a capacitor with a static switch consisting of a transistor.

Description

 The devices which are the subject of the invention make it possible to transmit, without contact or electrical connection, to a device distinct from information that another device has also communicated to it without contact or electrical connection.

 For the remainder of the description, the function performed by the devices which are the subject of the invention will be called: "dynamic coding".

 Currently, dynamic coding is done in two ways: a) With devices based on magnetic doublets which, according to their magnetic polarity, modify the frequency of an oscillator in + af, the interpretation of the sense of 8 f is associated with an information element (bit) 1 or O. The disadvantages of this system are that the information is transmitted in parallel form and therefore the size of the system is linked to the importance of this information , that the decoding system is expensive and complicated and that the material constituting the magnetic dipoles is very special and delicate to supply.

b) With a battery of frequency transmitters which act on a battery of frequency receivers: the information received actuates bistable relays which may or may not use frequency transmitters different from the previous ones and which restore their frequency to a battery of receivers The disadvantages of this system appear in the fact that the information is transmitted in parallel form and that the dimension of the system is linked to the importance of this information (this dimension is increased by the fact that the transmitters interfere with each other and must therefore be kept away) in the fact that the memorization is obtained by bistable relays which can offer contact hazards in the event of vibration and in the fact that it takes a lot of resources to implement , a lot of wiring and therefore a deterioration in overall reliability.

 N.B: The frequency transmitters / receivers can be replaced by light transmitters / receivers.

 The device which is the subject of the invention comprises: a programmable pad, a programming pad, one or more reading pads, a programming sequencer as well as a means which allows the programming pad to erase the programmable pad, a means which allows the programming pad to write information into the programmable pad, a means which allows the programming pad to re-read the information written in the programmable pad, a means which allows the programmable pad to acquire information from the programming pad, a means which allows the programmable pad to restore this information to the programming pad or the reading pad and a means which allows the programmable pad to memorize this information.

The programming pad receives an erasure signal from the programming sequencer, when the programmable pad receives this signal it goes into read position and emits in the vicinity of its transmission face an electromagnetic field.

The programming pad receives parallel information on its inputs, these bits of parallel information are supplied to an electronic device which transforms them into a serial electrical signal which activates or not a static switch, the latter closes or opens at the rate of this information series the active loop consisting of a turn engraved on a printed circuit, of a capacitor forming a series resonant circuit at the frequency of the electromagnetic field emitted by the programmable pad. Therefore, and by eddy current, the series resonant circuit of programming pad takes energy from the oscillator of the programmable pad, this is translated by an electrical signal which reflects the information in serial form appearing on the parallel inputs of the programming pad, this serial information is then recognized as valid by a electronic device of the programmable pad which analyzes the start, parity and end bits. If the information is correct, it is saved in parallel form in a memory.

Then, the programmable pad automatically enters the writing phase. Then, the parallel information stored is put in serial form by an electronic device which includes, upstream, a start bit and, downstream, a parity bit and end bits. This serial information is sent to a static switch which implements an active loop of the programmable pad, this active loop forms, with the static switch, a capacitor and the turn engraved on a printed circuit, a serial resonant circuit. This serial resonant circuit is closed or not by the static switch itself requested by the serial signal reflecting the parallel information stored by the programmable pad and sent to it by the programming pad.

The programming sequencer controls the programming pad in read mode, which has the effect of opening the active loop and of implementing an oscillator which emits an electromagnetic field in the vicinity of its receiving face.

The active loop of the programmable pad, tuned to this frequency, takes energy from this oscillator, the signal obtained is the serial reflection of the information stored in the memory by the programmable pad. An electronic device collects this serial electrical signal, verifies that it conforms, and restores it in parallel form to the parallel outputs of the programming pad.

The programming sequencer receives this parallel signal, compares it to the parallel signal which constitutes the information to be transmitted. If there is a tie, the programming sequencer indicates to the user that the programmable pad is correctly programmed, if not, the programming sequencer starts the erasing, programming, reading cycle. If at the end of three consecutive cycles, the programming pad does not restore the information that we want to transmit to it, the programming sequencer sends to the user a fault signal. If the programming sequencer sends a signal that informs that the programmable pad is correctly programmed, then the user can, for example, start from the mobile which supports the programmable pad and which will be read by reading pads placed along the path of the programmable pad.

At this point in the description, it should be noted that if the programmable and programming pads are at a correct distance, the operations ordered by the sequencer, namely erasing, programming, reading the programmed information and checking the programmed information takes place in the same geographic location without relative movement between the programmable pad and the programming pad.

When the user allows the programmable pad to pass in front of the reading pad, the transmission of the information contained in the programmable pad is done as follows: We know that when the programmable pad is programmed it implements, at the rate of the information contained, an active loop which draws energy by eddy current from any oscillator placed on its path. The read pad contains an oscillator whose frequency corresponds to the tuning frequency of the active loop of the programmable pad. Therefore, when the latter passes in front of the reading pad, at a distance less than or equal to the range, the active loop of the programmable pad takes energy, at the rate of the serial information, from the oscillator of the reading pad.

The signal obtained at the output of the oscillator is routed to an electronic device which restores it, in parallel form, to the parallel outputs of the read pad. The programmable pad also receives external information, in fact, the information restored consists of one or "logic of parallel information coming from the programming pad or from the external parallel inputs. In addition, the information programmed from the programming pad is saved in the programmable pad in the event of a power cut by an accumulator, part of which is integrated in the programmable pad.

The accompanying drawings illustrate, by way of example, an embodiment of the device according to the present invention.

Figures 1 and 2: PROGRAMMABLE PLOT - PROGRAMMING PLOT.

a) Erasure phase:
Consider that the programmable pad approaches the programming pad at a distance less than or equal to the range and stops next to it, that the programmable pad is in writing (transmission of its information) and that the programming pad is in reading position. Then: - For the programmable pad, the serial information signal (35) passes through the transmission inhibitor (14) to the static switch (15) which opens and closes, at the rate of the signal (35), the active loop (16-17-15) tuned to frequency f2. The read inhibitor (23) inhibits the oscillator (19) and thereby no electromagnetic field (39) of frequency f1 appears around the transmission face (38). Furthermore the voltage level of the line ( 37) is a high level in the absence of oscillation of the oscillator (19).

- For the programming pad, the read signal (45) authorizes the oscillator (54), tuned by the capacitors (57-58) in parallel, to emit by its induction coil (62) an electromagnetic field (63) of frequency f2 in front of its transmission face (64). Line (45), when active, uses the inhibitor (60) which opens the active loop (59-61-65) tuned to the frequency fi0 The active loop (15-16-17) takes energy, to the rhythm of the line (35) and by eddy current, to the oscillator (54). The signal thus modulated is rectified by the cell (53) and activates a threshold system (52) which restores a serial signal (46) identical to the serial signal (35). If the serial information received by the device (51) is correctly formed (start bit, parity bit and end of message bits) it is compared to a second piece of information which must itself be correctly formed. If the comparison is valid, line (44) becomes active. The parallel information appears on the lines (40) after having passed through the output device (49). The reading line (45) remains active. The erasing line (43) becomes active which opens the switch (56) and deactivates the tuning capacitor (57) of the oscillator (54). Therefore, the oscillation on (54) will oscillate at the frequency f1 (which is possible because the active loop (61-59-65) tuned to f1 is itself open). The electromagnetic field (63) of frequency fl goes 8trie collected by the induction coil (in), this received field will be modulated by the active loop (15-16-17), however, this signal will reach the rectification cell (20) and then the threshold system (21). The output signal (37) from the threshold system (31) is integrated by the cell (22). The output (29) of this cell sets the memory (24) to "O" which has the effect, by the signal (30), of implementing the inhibitor (14) of the active loop (15-16- 17) which remains open by the line (28), to implement the oscillator (19) by putting the inhibitor (23) out of service and to put the memory (12) in a position for receiving information (31 ) coming from the electronic device (13). The oscillator (19), by its coil (18), emits an electromagnetic field (39) of frequency fl around its transmission face (38).

In this state, the programmable pad is no longer in the transmission phase but in a reception (read) phase and its memory (12) is in the position for receiving data (31) from the device (139.

b) Programming phase:
Consider that the signals (43) and (45) are no longer active. The inverter (42) activates the inhibitor (55) so that the oscillator (54) does not oscillate and that no electromagnetic field (63) is emitted in front of the transmission face (64 ). On the other hand, the write inhibitor (60) is out of service and allows the active loop (61-65-59) to close or open at the rate of the signal (47). The parallel information (41) is processed by the input adapter (50) and routed to the electronic device (spi) which converts it into a serial electrical signal by including a start, parity and end bit. message. The active loop (59-61-65) thus requested by the signal (47) takes energy, by eddy current, from the oscillator (19) at the rate of the signal (47). rectified, filtered by the cell (20) and transmitted to the threshold system (21) which translates it into a serial electrical signal (37) image of the serial signal (47). If two consecutive messages have been recognized correctly formed (start bit, parity bit, end of message) and identical by the electronic device (13), the latter sends the information in parallel form to the memory (12) by the lines (31) then puts its active line (36), which has the effect, via the line (27), of modifying the state of the memory (24). The line (28) puts the memory (12) in a storage state which no longer receives any information coming from the lines (31), but on the other hand is evacuated towards the function "or" (11), by the lines (32), the parallel information received. The line (30) deactivates the write inhibitor (14) and the signal (35) can be routed to the active loop (15-16-17). Furthermore, the reception time of two consecutive messages is much less than the integration time constant of the cell (22), therefore, the line (29) cannot be active during this time. The "or" function (11) also receives external information (1) by the adaptation device (3) which it transmits to it by the lines (33). The "or" function is performed bit by bit and the resulting information is transmitted to the device (13) by the lines (34), the device (13) restores it in serial form on the line (35) by including bits dz start, parity and end of message. The signal (35) activates the active loop.

c) Control or proofreading phase
In this case, the external information (1) is set to "on.

It is assumed that the line (45) is active and the line (43) is not active, which has the effect of inhibiting the active loop (59-61-65) and disabling the oscillation oscillatorriz (55). Consequently, the oscillator (54) tuned by the capacitors (57-58) oscillates at the frequency f2 and emits by its coil (62) an electromagnetic chaw (63) of frequency f2 near its transmission face (64) . This field (63) is taken or not and by eddy current by the active loop (15-16-17) at the rate of the serial signal (35), which has the effect of modulating the amplitude of the oscillator (54 ) and obtain on the line (46) by the devices (53-52) a serial image signal of the serial signal (35). This signal (46) is processed by the device (51) which, if two consecutive messages and correctly formed are identical, makes the line (44) active and transmits by the output device (49) the parallel information on the output lines (40).

Figure 1 t PROGRAMMABLE PLOT Memorization of the information to be transmitted.

 The information to be transmitted is memorized by the memory (12) under memory control (24). The programmable pad is supplied from the sector (2) through an isolation transformer (4), a converter (5) which supplies power (9-10) to the electronic components apart from the memories (24 -12) and the sector alignment cut-off detection device (6). These devices (6), (12), (24) are supplied separately by a resident accumulator (7) which supplies the polarities (8) to the memories (12) and (24) and to the threshold device (6). , in the event of a mains supply, the charge of this accumulator is maintained from the supply (9), (10) by a network (25-26). In the event of a power outage, the device (6) detects this break and replaces on the line (27) the effect of the signal (36) before it disappears. As a result, the line (27) will not have changed state and when the mains supply (2) is restored the programmable pad will be in the position for transmitting the information saved in the memory (12). In the erasing phase, lines (36) and (27) are inactive, line (29) is active. If a power outage (2) occurs, line (29) becomes inactive but line (27) becomes active by l action of the threshold device (6), which has the effect of putting the programmable pad in the information writing position "on since the memory (12) will have been erased.

Figure 3: READING PLOT.

The active line (75) deactivates the oscillation inhibitor (77) which allows the oscillator (69) to oscillate and emit, by its coil (68), an electromagnetic frequency field (66) f2 in the vicinity of its transmission face (67).

By the rectifying cell (70) and the threshold device (71) the signal (79) becomes inactive and is interpreted by the device (72) as an erroneous message which has the effect of rendering the signal (76) inactive and the signal (78) active.

The active signal (78) intervenes at the output device (73) to put the outputs (74) inactive. If the signal (75) becomes inactive, as the signal (76) is itself inactive, the inhibitor (77) is out of service and the oscillator (69) emits its electromagnetic field (66). As soon as the programmable pad passes or remains in front of the transmission face at a distance less than or equal to the range, the active loop (15-16-17) takes energy by eddy current to the oscillator (69) at the rhythm of the serial signal (35). The cell (70) and the threshold detector (71) translate this energy withdrawal into a serial electrical signal (79) which is an image of the serial signal (35). If two consecutive correctly formed pieces of information are recognized identical by the device (72) this activates the line (76) which implements the inhibitor (77) which forces the line (79) to remain active and thereby memorize the information which appears on the lines (80). Furthermore, the signal (78) becomes inactive and allows the output device (73) to release the information present on the lines (80) to the outputs (74) until a new signal d erasure (75) occurs.

Figure 1-2: ACTIVE LOOP.

Both for the programming pad and for the programmable pad, the active loop consists of a static switch (15) or (59), a turn engraved on a printed circuit (61) or (17). A special feature of the invention resides in this turn engraved on a printed circuit which allows, by modifying its length, to have transmissions always possible when the programmable pad moves at high speed in front of the reading pad or when it stops. in front of it with great imprecision. The static switch (15-59), meanwhile, consists of a silicon transistor or a field effect transistor depending on the energy level available.

Figure 4 t PRE-PROGRAMMING SEQUENCER.

The sequencer receives the information on its lines (93) and sends it on the lines (92) which are to be connected to the lines (41) of the programming pad. The sequencer also receives the information received by the line programming pad (40) on its lines (91). As soon as the programmed block approaches the programming block, and communicates its resident information to it, the lines (44) and (90) become active and the information received by the programming block on the lines (40) appears on the lines ( 91) and via the input device (86) at the input of the comparator (85). The other entry (93) contains the information to be programmed in the programmable pad. The rise of the line (90) implements a monostable (81) which makes it possible to send an erasure signal (89) to the programming pad via the line (43). The fallout of the monostable signal (81) implements a new monostable (82) whose fallout of the signal causes the signal of the monostable (83) to drop, which generates the signal (88) connected to the line (45) of the programming pad. . As soon as the line (88) becomes active, the line (90) itself becomes active. The rise of the signal (88) makes it possible to advance a signal '11'l in the register (84). The information received on the lines (91) via the lines (86) is compared to the information (93). Normally, these two pieces of information must be equal if the programmable pad is correctly programmed.

In this case, the equality line (98) of the comparator (85) resets the register (84) to no "and indicates on the line (96) to the user that the programmable pad contains the correct information. on the contrary, as soon as the line (90) becomes active, if the comparison in the comparator (85) of the information on the lines (93) and (91) does not lead to a equality, the line (99) or (100) becomes activates and allows the start of a new implementation cycle for monostables (81), (82), (83) until equality is obtained or line (97) becomes active. , the finding of inequality (line 99,100) combined with the failure noted in the repetition of cycles (line 97 active) leads to a general fault (95) which warns the user An initialization device, line ( 94), is planned.

The device which is the subject of the invention can be used in all dynamic coding applications. Its interest lies in the fact that each object can be coded directly without using a conversion table between the object itself and its support.

Claims (29)

R E V E N D I C A T I O N S 1) Device for performing a dynamic coding operation, without contact or electrical connection between the coder and the assembly or object to be coded Characterized by the fact that it includes a means which allows the programming block (encoder) to influence, without contact or electrical connection, the programmable block to register a coda. Also characterized by the fact that the grammar prc pad can influence, without contact or electrical connection, the programming pad or a reading pad to restore the code entered. 2) Device according to claim 1, Characterized by the fact that the parallel information of the programmatd pad is translated into serial information.  3) Device according to claim 1, Characterized by the fact that the information (signal) from the programmntior block is transmitted in serial form, without contact or electrical connection, to the prc grammabla block by the closing or opening of a static switch which operates or not a resonant circuit series.  4) Device according to claim 1, Characterized by the fact that the serial resonant circuit of the programmatic block consists of a coil engraved on a printed circuit, a capacitor and a static switch.  5) Device according to claim 1, Characterized by the fact that the static switch consists of a saturated, blocked transistor. Characterized by the fact that the state of the programmable pad after power-up is: writing.  6) Device according to claim 1,  7) Device according to claim 1 Characterized by the fact that the series resonant circuit of the programming pad consisting of the turn, the capacitor and the static switch draws energy, by eddy current, from the reading oscillator of the programmable pad which has the effect of it will write the code. 8) Device according to claim 1, Characterized by the fact that the programmable pad goes into the writing position as soon as it is erased.  9) Device according to claim 1, Characterized by the fact that the programmable pad goes into the writing position as soon as it has received a correct code. 10) Device according to claim 1, Characterized by the fact that the serial information contains parity, start and end bits. 11) Device according to claim 1, Characterized by the fact that the programmable pad contains a series resonant circuit consisting of a coil engraved on a printed circuit, a capacitor and a static switch. 12) Device according to claim 1, Characterized by the fact that the series resonant circuit of the programming pad is tuned to the frequency of the readout oscillator of the programmable pad and that the resonant circuit of the programmable pad is tuned to the frequency of the readout oscillator of the programming pad or the reading pad.  13) Device according to claim 1, Characterized by the fact that the frequency of the readout oscillator of the programmable pad is different from that of the readout oscillator of the programming pad. 14) Device according to claim 1, Characterized by the fact that the programmable pad reproduces the code entered in the programming pad, or in the reading pad, by implementing its series resonant circuit which takes energy by eddy current from the reading oscillator of the programming pad or reading pad. Characterized by the fact that the code entered in the programmable pad can only be deleted by the programming pad.  15) Device according to claim 1, Characterized by the fact that, in order to erase the programmable pad, the programming pad sends, via its read oscillator, a high level of oscillation at the same frequency as that of the read oscillator of the programmable pad.  16) Device according to claim 1,  17) Device according to claim 1, Characterized by the fact that the erasing phases writing re-reading of the code are done by a single pad, in the same place and without contact or electrical connection between the programming pad and the programmable pad.  18) Device according to claim 1, Characterized by the fact that the programmable pad is supplied from the mains voltage.  19) Device according to claim 1, Characterized by the fact that the programmable pad detects a power outage.  20) Device according to claim 1, Characterized by the fact that a power outage implements a device for saving the registered code.  21) Device according to claim 1, Characterized by the fact that the saved code is saved by a memory powered by a rechargeable battery.  22) Device according to claim 1 Characterized by the fact that the programmable pad provides the holding current for the accumulator.  23) Device according to claim 1, Characterized by the fact that the programmable pad receives parallel external information. 24) Device according to claim 1, Characterized by the fact that the erasing, writing and reading phases are controlled by a sequencer.  25) Device according to claim 1, Characterized by the fact that the sequencer compares the written and re-read code of the programmable pad to the code to be written. 26) Device according to claim 1, Characterized by the fact that if the written code conforms to the code to be written, the sequencer generates a validation signal.  27) Device according to claim 1, Characterized by the fact that if the read code read is different from the code to be written, the sequencer restarts an erase, write, read phase. 28) Device according to claim 1, Characterized by the fact that if at the end of three erasing, writing and reading phases, the re-written code remains different from the code to be written, the sequencer generates a fault signal. 29) Device according to claim 1; Characterized by the fact that the reading pad memorizes or not the code written by the programmable pad.