FR2678729A1 - Odometer for motor vehicles - Google Patents

Abstract

The present invention relates to an odometer for a motor vehicle, characterised in that it comprises an electronic circuit including at least one general counter (240) designed to be incremented by an input signal representing the movement of the vehicle, so that the content of the counter (240) represents the distance travelled by the vehicle, at least one non-volatile memory (400) designed to receive data from the general counter (240) in order to safeguard these data and means which allow conditional resetting of the general counter (240).

Description

 The present invention relates to the field of odometers for motor vehicles, that is to say the field of instruments which indicate the distance traveled by motor vehicles.

 The object of the present invention is to improve the known odometers. One of the aims of the present invention is in particular to propose an odometer capable of being associated with a wide range of input speed sensors and with a wide range of output indicators.

 These aims are achieved according to the present invention by means of an odometer for a motor vehicle, characterized in that it comprises an electronic circuit comprising at least one general counter designed to be incremented by an input signal representative of the movement of the vehicle, so that the content of the counter is representative of the distance traveled by the vehicle, at least one non-volatile memory designed to receive data from the general counter in order to save these, and means which authorize a conditional reset of the general counter .

 According to another advantageous characteristic of the present invention, the non-volatile memory is designed to memorize, as and when they appear, data representing several successive distance units counted by the general counter, as well as coding bits of these data, and means are provided capable of checking, during reading, the coding bits and the adjacency between the data, in order to correct the possibly erroneous data stored in the non-volatile memory.

 According to another advantageous characteristic of the present invention, the non-volatile memory is designed to store data representing the last four units of distance traveled counted by the general counter.

 According to another advantageous characteristic of the present invention, the electronic circuit is supplied by the most permanent of the vehicle formed by a line directly connected to the vehicle battery.

 According to another advantageous characteristic of the present invention, the circuit includes means capable of monitoring the presence of the voltage on the After Contact Power line in order to control the transfer of the content of the general counter in the non-volatile memory in the event of a power failure. voltage on the After Contact Power line.

 According to another advantageous characteristic of the present invention, the circuit further comprises a partial counter capable of accounting for the distance traveled by the vehicle from an origin capable of being reset to zero by the driver.

 Preferably the means which authorize a conditional reset of the general counter, limit the resets of the general counter to zero in number and / or under a defined distance traveled limit.

 Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows and with reference to the appended drawings given by way of nonlimiting example and in which - FIG. 1 represents a block diagram, in the form of functional blocks, of the structure of a circuit in accordance with the present invention, - Figure 2 represents a general flowchart of the operation of the odometer device in accordance with the present invention, and - Figure 3 represents a detailed flowchart of the operation of the odometer device according to the present invention.

 The circuit according to the present invention shown in the attached FIG. I is organized around three buses: an address bus 100, a data bus 110 and a command and flags bus 120.

 The circuit shown in FIG. 1 mainly comprises the following modules - a totalizer 200, - input interfaces 300, - a non-volatile memory 400, - a sequencer 500, - a module 600 for validation of the stored data, - a power supply monitoring module 700, - an output interface 800, and - a clock 900.

 The odometer display is referenced AFF. It is preferably an electro-optical display, for example a liquid crystal display.

 The various modules 200 to 900 mentioned above are supplied via the most permanent of the motor vehicle (+ PER), that is to say a supply line connected directly to the vehicle battery without passing through the contactor controlled by the ignition key, so that the most permanent remains present regardless of the position of the ignition key, as long as the vehicle battery is not disconnected.

 The totalizer module 200 essentially comprises a shaping circuit 210, an accumulation register 220, an adder 230, a general counter 240 and a partial counter 250.

 The shaping circuit 210 receives on its input 211 an input signal representative of the speed of the vehicle, or more precisely of the displacement thereof. This input signal generally comes from an electrical sensor placed at the output of the gearbox. Information representative of the movement of the vehicle can be provided by the amplitude of the input signal. However, preferably the information representative of the movement of the vehicle corresponds to the frequency of the input signal applied to the shaping circuit 210. The shaping circuit 210 can be formed for example of a Schmitt trigger.

 The accumulator register 220 with two inputs: 221 and 222. I1 receives on its increment input 221, the signal coming from the output 212 of the shaping circuit 210. The output 223 of the accumulator register 220 is an output at X bits , for example at 14 bits. It is looped back to its main input 222 via the adder 230. More specifically, one of the inputs 231 of the adder 230, at X bits, is connected to the output 223 of the accumulator register 220, while the second input 232 of the adder 230 is connected to the data bus 110 to receive, from one of the interface modules 320, a configuration parameter linked to the structure and the nature of the sensor generating the signal d input. The second input 232 of the adder 230 typically has XI bit, for example 13 bits. The output 233 of the adder 230 is connected to the input 222 of the accumulator register 220. The output 233 of the adder 230 and the input 222 of the accumulator register 220 typically have X bits.

 The most significant output 223 of the accumulator register 220 is connected to the incrementing inputs 241, 251, of the general counter 240 and of the partial counter 250 respectively.

 The outputs 242, 252 at Y and Z bits of the general counter 240 and of the partial counter 250 are connected to the data bus 110. A reset input 243 of the general counter 240 is connected to the bus 120. The function of this input of general reset 243 will be explained later.

 Similarly, a reset input 253 of the partial counter 250 is connected to the bus 120.

 The most significant output 244 of the general counter 240, which corresponds to the accounting of the units of distance traveled and therefore to the overflow of the counter 240, is connected to the address bus 100. This output 244 which corresponds to the overflow of the counter general 240 intervening at each unit of distance traveled, is used to trigger a backup write in the non-volatile memory 400, as will be explained below.

 The units of distance traveled can be kilometers or another basic unit, for example the mile.

 The outputs 242 of the general counter 240 thus represent, in sub-units, for example in hectometers, the distance traveled by the vehicle in the last unit of distance traveled recorded. The previous distance traveled units are counted in the non-volatile memory 400.

 The outputs 252 of the partial counter 250 for their part represent the distance, in units of distance and sub-units of distance, for example in kilometers and hectometers, traveled by the vehicle from an origin capable of being reset by the driver.

 The interface modules 300 are preferably four in number - a detection module 310 + APC, - a serial interface module 320, - a display selection and reset module 330, and - a module of tests 340.

 The detection module 310 + APC has the function of monitoring the state of the After Contact Power line, that is to say the power line of the vehicle passing through the contactor controlled by the ignition key.

The interface 310 thus samples the information + APC. In the presence of a cut in the + APC, the module 310 sets a flag on the bus 120. This positioning triggers the implementation of a "MODE
BACKUP ". This will be specified later. However, it can now be indicated that, during this BACKUP MODE, the sequencer 500 causes the content of the general counter 240 to be transferred to the non-volatile memory 400.

 Preferably, the circuit shown in the attached FIG. 1 is protected by an external network which filters micro-cuts with a duration of less than 2 ms.

 The + APC line is therefore connected to the input 311 of the module 310. The output 315 of the module 310 is connected to the bus 120.

 The serial interface 320 is intended to provide, to the circuit, parameters for configuring the function, for example parameters linked to the input sensor.

 By using such configuration parameters, the circuit shown in Figure 1 can cover a wide range of applications.

 The serial interface module 320 comprises three inputs: a data line 321, a clock line 322 and a validation line 323. The taking into account of the data present on the input 321 is only authorized when the line validation 323 is in a determined state, the low state for example.

 The configuration parameters preferably include configuration bits of the summation operation for the totalizer module 200, more precisely the input 232 of the adder 230, and display configuration bits taking into account the nature of the particular display used.

 A key is preferably provided to prevent any untimely writing on the module 320.

 The configuration parameters thus introduced by the module 320 are stored in the non-volatile memory 400.

 The output 325 of the module 320 is connected to the data bus 110.

 The module 330 includes two inputs 331, 332 used respectively to operate a display selection and to reset the system.

 The display selection input 331 makes it possible to select the display of the content of the general counter 240 or of the content of the partial counter 250 on the display AFF, in the case of a single display.

 The reset input 332 makes it possible to control the reset of the general counter 240 and the partial counter 250, respectively using the inputs 243 and 253.

 However according to the invention the reset of the general counter 240 is a conditional reset.

 According to an advantageous characteristic of the present invention, the resetting of the general counter 240, using the input 243, is only authorized if the distance traveled is less than a determined value and is only authorized a limited number of times.

 Very preferably, resetting the general counter 240 is only valid if the distance traveled is less than 200 km and is only authorized twice. Thanks to such an arrangement, the equipment manufacturer of the odometer can carry out a first reset after testing. Likewise, the car manufacturer can carry out a second reset, after installation of the odometer on the vehicle and appropriate tests.

 The output 335 of the module 330 is connected to the bus 120.

 Module 340 is a general circuit test module. Indeed, preferably, all of the modules 200 to 900 are produced in the form of an integrated circuit.

 Two inputs 341, 342 have been shown diagrammatically for the test module 340 in FIG. 1. The output 345 of the module 340 is connected to the bus 120.

 The non-volatile memory 400 has an address entry 401 connected to the bus 100 and a data entry 402 connected to the bus 110.

 The non-volatile memory 400 is designed to store the totalization parameters from the input 321 of the serial interface 320 and applied to the input 231 of the adder 230, the display configuration parameters from the same input 321 of the serial interface 320 and used by the output interface module 800, data representing several last units of distance traveled, for example several last kilometers counted by the general counter 240, in the form of a backup battery distance traveled, a pointer to the distance traveled backup battery, as well as the content of the general counter 240 in BACKUP MODE. The data of the backup battery and the backup battery pointer contained in the non-volatile memory 400 evolve at each overflow of the general counter 240, that is to say each new unit of distance traveled, for example each new kilometer traveled, d onc on each validation of the output 244 of the general counter 240. On the other hand, the data representing the complete content of the general counter 240, which are contained in the non-volatile memory 400, are refreshed only when the + cut is detected. APC, when switching to BACKUP MODE.

 Preferably, the backup battery contained in the non-volatile memory 400 is designed to store the last four units of distance traveled, for example the last four kilometers counted by the general counter 240, that is to say the last four overflows. detected on the output 244 of the general counter 240. The backup battery contained in the non-volatile memory 400 also contains bits coding bits representing these last four units of distance traveled. The coding bits are preferably formed of parity bits per byte.

 The memorization of several last recorded distance units makes it possible to ensure the integrity of the memorized information, despite the risk of disturbance in the data, when the memorization is carried out in a parasitic environment. Indeed, as will be explained later, this process makes it possible to correct possibly erroneous data stored in non-volatile memory 400. These data, four in number according to the preferred embodiment of the present invention, will be referenced respectively. N-3, N-2, Nl and N thereafter.

 When the last four units of distance traveled are stored in non-volatile memory 400, the stack pointer is a pointer on two bits which evolves with each overflow of the output 244 of the general counter 240.

 The non-volatile memory 400 can for example be a non-volatile memory with 16 bytes.

The sequencer 500 is controlled by the oscillator 900. This oscillator 900 can for example be an RC oscillator with a basic frequency of the order of 30 kHz. The sequencer 500 controls the operation of the circuit between the following four modes: 1) STANDBY MODE, 2) MODE
ACTIVATION, 3) BACKUP MODE, 4) POWER OFF MODE, depending on the state of the + APC and the + PER. It controls in particular the progress of write / read operations in the non-volatile memory 400, in MODE
ACTIVATION, as well as the storage and saving procedures associated with the fall in + APC detected by the interface module 310.

 Furthermore, the sequencer 500 controls the verification of the data stored in the non-volatile memory 400 by the module 600.

 The function of the sequencer will be specified below in the context of the description of the operation with regard to FIGS. 2 and 3.

 The sequencer 500 has an address line 501 connected to the bus 100 and a control line 502 connected to the bus 120.

 The validation module 600 has an address input 601 connected to the address bus 100, a data input 602 connected to the data bus 110 and a command input 603 connected to the command bus 120.

 The module 700 includes two sets 710, 720 which respectively detect the entry into service of the power supply + PER and the interruption of the latter. The assemblies 710, 720 are connected to the bus 120.

 The output interface 800 provides transcoding of the binary data representing the valid distance traveled from the module 600, in control compatible with the pilot circuits of the display AFF.

 For this, the output interface 800 has an input 801 connected to the output of the validation module 600, an input 802 connected to the bus 120 and an output 803 connected to the pilot circuit of the display AFF. Preferably, this AFF display is a liquid crystal display.

 It will be noted that according to a preferred characteristic of the invention, the system further comprises a module 610 connected to the data bus 110 and which defines a characteristic for correcting the power supply parameters of the display AFF as a function of the temperature.

The general operation of the device shown in Figure 2 is as follows
STANDBY MODE 1000 is the mode controlled by the sequencer 500, when the vehicle battery is connected, and therefore the + PER is present without however the + APC being present.

 When the module 310 detects the + APC, the sequencer 500 commands the passage from STANDBY MODE 1000 to ACTIVATION MODE 1100.

When on the other hand the module 310 detects the fall of the + APC, the sequencer 500 commands the passage from the ACTIVATION MODE 1100 to
SAVE MODE 1200.

The end of SAVE MODE 1200 is followed by MODE
STANDBY 1000 when the + PER remains present and is followed by the OFF MODE
VOLTAGE 1300 when on the contrary the + PER is absent.

The sequencer 500 finally controls the passage of the MODE
STANDBY 1000 to OFF MODE 1300 when the + PER drops and conversely switching from OFF MODE 1300 to STANDBY MODE 1000 when implementing the + PER.

 We will now describe the detailed operation of the device with reference to FIG. 3.

 In STANDBY MODE 1000, totalization using counters 240, 250 and access to non-volatile memory 400 are inhibited.

 In STANDBY MODE 1000, the sequencer 500 continuously scans, in step 1010, if the + APC is established.

If so, the sequencer 500 places the system in
UPDATE MODE 1100.

 If not, the sequencer 500 remains in STANDBY MODE passing through step 1020 for interrogating the presence of the + PER. The continuation of step 1020 will be specified below.

 The ACTIVATION MODE consists of the following sequence.

 In step 1110, the sequencer 500 examines whether the + PER was previously cut.

 If so, the information on the counter 240 is no longer significant. In this case, the sequencer 500 then reads, in step 1120, from the non-volatile memory 400, the data saved from the general counter 240 (ie the value in sub-units, for example in hectometers from the general counter 240) and reloads the counter. general 240 at this value.

 Step 1120 is followed by step 1130.

 Likewise step 1110, when it leads to a negative response, is followed by step 1130. In fact in this case the general counter 240 supplied by the + PER has kept its content.

 Step 1130 consists in - reading the configuration parameters of the odometer, saved in the non-volatile memory 400, and applying these parameters to the input 232 of the adder 230, - then authorizing the counting on the general counter 240 and the partial counter 250, - read the pointer to save the distance traveled, - read the parameters of the AFF display.

 Furthermore, in ACTIVATION MODE, the reading sequence controlled by the sequencer 500 cyclically includes a verification 1140 of the integrity of the four "distance traveled" data stored in the backup stack of the non-volatile memory 400, because this parameter is a fundamental parameter. To do this at the rate of the updating of the display, the sequencer 500 commands the following sequence - reading of the data N-3 contained in the backup battery of the non-volatile memory 400, that is to say ie the oldest data stored, - verification of this data using associated coding, preferably verification of parity, - reading of data N-2, - verification of coding (parity), - verification of the adjacency between the data N-3 and N-2, that is to say verification of the fact that the difference between N-3 and N-2 is indeed equal to one kilometer, - reading of the data Nl, - coding check (parity), - ver ification of the adjacency between the data N-1 and N-2, - reading of the data N, - verification of the coding (parity), - verification of the adjacency between the data N and Nl, - if necessary, reconstruction of the valid data N (good parity and good continuity), and display of the valid data on the AFF display.

 The sequencer 500 then monitors in step 1150 if the general counter 240 has recorded a new complete unit of distance traveled, for example a complete kilometer.

 If so, a "distance traveled unit overflow" flag is detected on output 244 of general counter 240. In this case, step 1150 is followed by next step 1160 - reading the pointer from the backup battery in the non-volatile memory 400, - reading of the data pointed by the pointer, - incrementing of the data, - incrementing of the pointer (modulo 4), - writing of the incremented data with its coding bits in the memory backup battery no volatile 400, and - reset to zero of the "overflow distance unit" flag.

 The four data N-3, N-2, N-1 and N are thus refreshed cyclically.

 Step 1160 is then followed by step 1170.

 Similarly, the interrogation step 1150, when it gives a negative response, is followed by step 1170.

 During this step 1170, the sequencer scans for the presence of the + APC.

 If a fall in the + APC is not detected, the operation loops back to step 1140.

 The counting and the display of the distance traveled then continue normally.

 On the other hand, if in step 1170, a fall in the + APC is detected, then the circuit switches to SAVE MODE 1200.

 Comparably to step 1150, the sequencer 500 examines in step 1210 whether the general counter 240 has recorded a new unit of distance traveled, for example a new complete kilometer.

 If so, a “distance traveled overflow” flag is detected on output 244 of the general counter 240. In this case step 1210 is followed by the following step 1220, similar to step 1160 - reading of the pointer from the backup battery in non-volatile memory 400, - reading of the data pointed by the pointer, - incrementing of the data, - incrementing of the pointer (modulo 4), - writing of the incremented data with its coding bits in the back-up battery of the non-volatile memory 400, and - resetting to zero of the "overflow distance unit" flag.

 Step 2020 is then followed by step 2030.

 Likewise, the interrogation step 2010, when it gives a negative response, is followed by step 2030.

 During the stamp 2030, the sequencer 500 saves data by writing the address of the stack pointer and all of the content of the general counter 240, in units of distance traveled, (hectometers) included, in non-volatile memory 400.

 Step 2030 is then followed by the aforementioned step 1020.

 If during step 1020, it is detected that the + PER remains present, the system switches from BACKUP MODE to STANDBY MODE.

On the other hand, if during step 1020 it is detected that the + PER is cut, the system switches from BACKUP MODE to OFF MODE
VOLTAGE 1300.

 The fundamental data remain stored in non-volatile memory 400.

 In the POWER OFF mode, the sequencer 500 monitors the presence + PER in step 1310.

 The system remains in POWER OFF mode until the presence of + PER is detected.

 As soon as the + PER is detected in step 1310, the system switches to STANDBY MODE 1000.

 The process described above does not entail any loss of precision both in the general counter 240 and in the partial counter 250 in the event of the + APC drop. Indeed, in this case the circuit being supplied by the + PER, the data is saved respectively in the general counter 240 and in the partial counter 250, with redundancy in the non-volatile memory 400 for the sub-units (hectometers) of the general counter 240.

 In the event of a cut in the + PER, the sub-units (hectometers) of the general counter are stored in non-volatile memory 400.

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

 In particular, if desired, the capacity of the non-volatile memory 400 can be adapted to permanently store in activation mode several last distance traveled units recorded by the partial counter 250 and / or transfer to the non-volatile memory 400, the content of the partial counter 250 when the + APC is cut in order to save this data in the event of a later cut of the + PER.

Claims (13)

 1. Odometer for a motor vehicle, characterized in that it comprises an electronic circuit comprising at least one general counter (240) designed to be incremented by an input signal representative of the movement of the vehicle, so that the content of the counter (240) is representative of the distance traveled by the vehicle, at least one non-volatile memory (400) designed to receive data from the general counter (240) in order to save these and means (330) which authorize a reset to conditional zero of the general counter (240).  2. Odometer according to claim 1, characterized in that the means (330) authorizing a conditional reset of the general counter (240), limit the resets of the general counter (240), in number, and / or under a distance traveled defined limit.  3. Odometer according to claim 2, characterized in that the means (330) authorizing a conditional reset of the general counter (240), limit the number of resets of the general counter (240) to two and under 200 km traveled .  4. Odometer according to one of claims 1 to 3, characterized in that the non-volatile memory (400) is designed to memorize, as and when they appear, the data representing several successive distance traveled units counted by the general counter (240), as well as coding bits for these data, and means (600) are provided capable of checking, during reading, the coding bits and the adjacency between the data, in order to correct any erroneous data stored in the non-volatile memory.  5. Odometer according to claim 4, characterized in that the non-volatile memory (400) is designed to store data representing the last four units of distance traveled counted by the general counter (240).  6. Odometer according to one of claims 1 to 5, characterized in that the electronic circuit is powered by the most permanent of the motor vehicle (+ PER) formed by a line directly connected to the vehicle battery.  7. Odometer according to one of claims 1 to 6, characterized in that it comprises means suitable for monitoring the voltage on the After Contact Supply Line (+ APC), in order to control the transfer of the complete content of the general counter in non-volatile memory (400) in the event of a voltage cut on this Supply line After Contact (+ APC).  8. Odometer according to one of claims 1 to 7, characterized in that the circuit further comprises a partial counter (250) capable of accounting for the distance traveled by the vehicle from an origin capable of being handed over to zero by the driver.  9. Odometer according to claim 8, characterized in that the content of the partial register (250) is reset to zero in the event of interruption of the most permanent formed by a supply line directly connected to the vehicle battery.  10. Odometer according to one of claims 8 or 9, characterized in that the content of the partial register (250) is saved in the non-volatile memory in the event of a voltage cut on the After Contact Supply line (+ APC).  11. odometer according to one of claims 1 to 10, characterized in that the input signal is applied to the input of an accumulator register (220) whose output (223) is connected to an input (231 ) of an adder (230) which receives on its second input (232) a configuration word and whose output (233) is connected to a second input (222) of the accumulator register, the output (223) of this register ( 220) serving as an increment input for the general counter (240).  12. Odometer according to claim 11, characterized in that the configuration word is saved in the non-volatile memory (400).  13. Odometer according to one of claims 1 to 12, characterized in that the parameters of the display (AFF) are also saved in the non-volatile memory (400).