FR2969429A1 - Coding device for communicating body that transmits binary numbers in e.g. multiplexed communication network, has bits between most and least significant bits, where bits are characterized such that codes are provided as binary numbers - Google Patents

Abstract

The device (D1) has a sequence of N' bits that is provided between a most significant bit and a least significant bit. A set of code bits having binary number is provided from a string extracted from the sequence of N' bits. Another set of code bits having another binary number characterizes the sequence of N' bits such that a set of codes are provided as binary numbers. The binary numbers are formed in the presence of minimal value that equals to zero by removing all bits having a zero value. An independent claim is also included for a decoding unit for a communicating body.

Description

The invention relates to communicating members which are intended to be connected to a multiplexed communication network, equipping a system, such as for example and not limited to a vehicle, possibly of automotive type Zo, in order to exchange binary numbers. The term "communicating organ" here means an electronic equipment capable of transmitting, receiving and processing multiplexed frames including in particular binary numbers representative of values that can take at least one parameter. It may, for example, be computers, sensors or actuators. In addition, the term "multiplexed communication network" herein refers to a computer network comprising at least one bus to which connected (communicating) devices intended to exchange information data by means of multiplexed frames are connected. The invention therefore relates, in particular, to networks of CAN LS ("Controller Area Network Low Speed"), CAN HS ("Controller Area Network High Speed"), VAN ("Vehicle Area Network"), LIN ("Local Interconnect Network "), FlexRay, and all their variants. Such networks are used in many fields, and particularly in the field of vehicles (possibly of the automotive type). It is recalled that three types of data flow in a multiplexed communication network: the binary data (of value equal to 0 or 1 or true or false) which are coded on a single bit, the enumerated ones (of equal value to activated or not activated or in default, for example) which are encoded on a number of bits which depends on the number of possible states of the listed enumerated, and the digital data which are representative of parameter values and encoded on a number N of bits with a given resolution and a fixed offset (or offset) given. The development of a multiplexed communication network is a long and complex operation because it requires the understanding of a maximum of error situations and the discovery of solutions (including software) to prevent these situations from occurring. error occur. It is therefore particularly advantageous to be able to reuse in a new system under development a multiplexed communication network that has been developed for another system. Thus, it would be particularly interesting (especially) for vehicle manufacturers to be able to use the same multiplexed communication network for all versions of the same vehicle model, or even for several different models. However, the more sophisticated versions of a model, the higher the number of digital data to be exchanged their communicating organs, and therefore the more the multiplexed communication network may be saturated. Therefore, when a network (multiplexed communication) is saturated, and therefore unsuited to a version of a given model, one generally chooses to add one or more buses to this network, which requires only a number of relatively limited developments. However, increasing the number of buses in a network leads to an increase in the complexity (and cost) of the computers that must manage these buses. It can then result, possibly, an increase in weight and bulk if the buses are interconnected by specific gateway boxes (not integrated with an existing computer). The object of the invention is in particular to allow the integration of new communicating functions in a given multiplexed communication network, without this modifying the architecture of this network, thanks to a minimization of the burden induced by the transmission of additional information. by encoding the exchanged digital data which defines binary numbers representative of values which can take at least one parameter, which are between a minimum value Vmin and a maximum value Vmax, and whose (maximum) precision is chosen. It proposes in particular for this purpose a coding device, intended to equip a communicating organ able to transmit in a multiplexed communication network binary numbers of the aforementioned type, and arranged, in the presence of a binary number NB, consisting of a sequence of N1 bits (ordered between a first bit of highest weight and a last bit of least significant weight) and to be transmitted via a total number of bits less than N1 and function of a selected precision, to constitute, of firstly, a first N2 bit coded bit C1 from a bit string extracted from the N1 bit sequence of the number NB, and secondly a second coded bit number C2 which characterizes the positioning in the following N1 bits of the number NB of the bit string extracted (which participates in the constitution of Cl), so that these first C1 and second C2 coded bits are transmitted in place of the binary number NB. The coding device according to the invention can comprise other characteristics that can be taken separately or in combination, and in particular: it can be arranged to build the first coded bit number C1 by eliminating at least a portion of the zero value bits; which are located before the first bit of value equal to one (1) of the sequence of N1 bits, this part comprising a number NS of bits at most equal to N1 - N2, as well as a part of the bits of the sequence of N1 bits which are located from its last bit, so that it remains a chain of N2 bits, this part having a number Ni, of bits at most equal to N1 - N2; the second coded binary number C2 can characterize the positioning in the sequence of N1 bits of the number NB of the least significant bit of the bit string extracted which consists of the bits not deleted from the sequence of N1 bits of the number NB ; alternatively, the second coded binary number C2 can characterize the positioning in the sequence of N1 bits of the number NB of the most significant bit of the bit string extracted which is constituted by the bits not deleted from the sequence of N1 bits number NB; in a first variant, it can be arranged, in the presence of a minimum value Vmin equal to zero, to construct the first coded bit number C1 by deleting all the zero-valued bits that are located before the first bit of value equal to one (1) of the sequence of N1 bits, and this first bit having a value equal to one (1), then to determine the value Nd equal to N2 - Nr, where Nr is equal to the number of bits remaining in the sequence of N1 bits of the number NB after the deletion, then either to delete a number of bits equal to INdI starting from the last of the Nr bits remaining in the binary number NB after the deletion, if this value Nd is negative, in order to constitute the first number coded binary Cl, or to add a number equal to INd 'of zero value bits (0) after the last of the Nr bits remaining in the sequence of N1 bits of the number NB after the deletion, if the value Nd is positive, in order to constitute the first coded binary number C 1, again to constitute the first coded binary number C1 with the Nr bits remaining in the sequence of N1 bits of the number NB if the value Nd is zero, and the second coded binary number C2 then characterizing the positioning in the sequence of N1 bits the number NB of the most significant bit of the first coded bit C1; in a second variant, it can be arranged, in the presence of a minimum value Vmin other than zero, to construct the first coded bit number C1 by deleting all the zero value bits which are located before the first bit of value equal to one (1) of the sequence of N1 bits, and this first bit having a value equal to one (1), then to determine the value Nd equal to N2 - Nr, where Nr is equal to the number of bits remaining in the sequence of N1 bits of the number NB after the deletion, then either to delete a number of bits equal to INdI starting from the last of the Nr bits remaining in the binary number NB after the deletion, if this value Nd is negative, in order to constitute the first number coded binary C1, ie to constitute the first coded binary number C1 with the Nr bits remaining in the sequence of N1 bits of the number NB if the value Nd is zero, and the second coded binary number C2 then characterizing the positioning in the sequence of N1 bits of u NB number of the least significant bit or the strongest bit of the first coded bit C1; it can be arranged to constitute first C1 and second C2 coded binary numbers representative of binary numbers which are each equal to the current value of a parameter divided by the minimum value Vmin that this parameter can take, when this parameter is no nothing. The invention also proposes a first decoding device, intended to equip a communicating member adapted to receive from a multiplexed communication network first C1 and second C2 binary numbers coded by a coding device of the type of that presented above and representative of NB binary numbers to be reconstructed comprising N1 bits. This first decoding device, which is adapted to the case where Cl has been constructed by deleting high-order bits of zero value, and where C2 characterizes the positioning in the sequence of N1 bits of a number NB of the most significant bit. weak of C1, is characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of N1 bits of a number NB, i) to form a field of N1 bits whose the values are all nil, then ii) to replace bits of this field with the bits of the first coded bit Cl starting with the least significant bit whose weight within the field is equal to the decimal value defined by the second coded binary number C2, in order to reconstitute a string of N1 bits representative of the binary number NB with a chosen precision.

The invention also proposes a variant of the first decoding device, intended to equip a communicating member adapted to receive from a multiplexed communication network first C1 and second C2 binary numbers encoded by a coding device of the type presented below. before and representative of NB binary numbers to be reconstructed comprising N1 bits. This first decoding device, which is adapted to the case where Cl has been constructed by deleting high-order bits of zero value (0), and where C2 characterizes the positioning in the sequence of N1 bits of a number NB of the bit of highest weight of Cl, is characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of N1 bits of a number NB, i) to constitute a field of N1 bits whose values are all nil, then ii) to replace bits of this field with the bits of the first coded bit number C1 starting with the most significant bit whose weight within the field is equal to the value decimal defined by the second coded binary number C2, in order to reconstruct a N1 bit string representative of the binary number NB with a chosen precision. The invention also proposes a second decoding device, intended to equip a communicating member adapted to receive from a multiplexed communication network first C1 and second C2 binary numbers coded by a coding device of the type of that presented above and representative of NB binary numbers to be reconstructed comprising N1 bits. This second decoding device, which is adapted to the case where Cl has been constructed by deleting high-order bits of zero value (0) and the first most significant bit of value equal to one (1) located just after these bits of null value, is characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of N1 bits of a number NB, i) to form a field of N1 bits whose values are all nil, then ii) to replace bits of this field with the bits of the first coded binary number Cl beginning with the most significant bit whose weight within the field is equal to the decimal value defined by the second coded bit number C2, and iii) for replacing by a bit of value equal to one the bit of this field which is located just before that which has been replaced by the first most significant bit of the first coded bit C1, in order to piece together a string of N1 bits representing entative of the NB binary number with a chosen precision. The invention also proposes a variant of the second decoding device, intended to equip a communicating member adapted to receive from a multiplexed communication network the first C1 and second C2 binary numbers coded by a coding device of the type presented below. before and representative of NB binary numbers to be reconstructed comprising N1 bits. This second decoding device, which is adapted to the case where Cl has been constructed by deleting high-order bits of zero value (0) and the first most significant bit of value equal to one (1) located just after these bits of null value, is characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of N1 bits of a number NB, i) to form a field of N1 bits whose values are all nil, then ii) to replace bits of this field with the bits of the first coded binary number Cl beginning with the least significant bit whose weight within the field is equal to the decimal value defined by the second coded bit number C2, and iii) for replacing by a bit of value equal to one the bit of this field which is located just before that which has been replaced by the first most significant bit of the first coded bit C1, in order to reconstruct a string of N1 bits repr sentative of the binary number NB with a selected precision. The invention also proposes a communicating organ, intended to be connected to a multiplexed communication network for receiving and / or transmitting binary numbers, and comprising a coding device of the type of the one presented above and / or a first device for decoding of the type of the one presented above or a variant of the first decoding device of the type described above or a second decoding device of the type described above or alternatively a variant of the second decoding device of the type from the one presented above. The invention is particularly well suited, although not limited to, in the case where the communicating members are connected to at least one multiplexed communication network which is part of a system such as a vehicle, possibly of automotive type. Other features and advantages of the invention will appear on examining the detailed description below, and the accompanying drawing, in which the single figure schematically and functionally illustrates an example of a multiplexed communication network to which organs are connected. communicating each comprising a coding device according to the invention and a decoding device according to the invention. The attached drawing may not only serve to complete the invention, but also contribute to its definition, if any. The object of the invention is to provide a coding device D1 and corresponding decoding devices D2 intended to equip (separately or jointly) a communicating member Oi intended to be connected to a multiplexed communication network R of a system, in order to to transmit and / or receive multiplexed frames including in particular binary numbers representing values that can take at least one parameter. It should be noted that the invention relates to the coding and decoding of binary numbers NB which are representative of parameter values (s) lying between a minimum value Vmin and a maximum value Vmax and each consisting of a sequence of N1 bits ordered between a first most significant bit (MSB) and one last least significant bit (LSB). In what follows we consider, as is the case traditionally, that the first bit is the one that is located on the left, while the last bit is the one located most right 1 o. Furthermore, it is considered in the following, by way of non-limiting example, that the system is a motor vehicle, such as a car. But, the invention is not limited to this type of system. It concerns indeed any type of system comprising at least one multiplexed communication network R, including land vehicles, boats and aircraft, and industrial facilities. In addition, it is considered in the following, by way of non-limiting example, that the multiplexed communication network R is a CAN HS type network ("Controller Area Network High Speed"). However, the invention is not limited to this type of multiplexed communication network. It concerns indeed any type of multiplexed communication network comprising at least one bus (BUi), and in particular the CAN LS ("Controller Area Network Low Speed"), VAN ("Vehicle Area Network"), LIN (" Local Interconnect Network ") and FlexRay. A single (multiplexed) communication network R comprising a single bus B to which five communicating elements 01 to 05 (i = 1 to 5) for exchanging data is schematically illustrated is illustrated in the single figure. information (digital) using multiplexed frames. The term "communicating organ" herein refers to electronic equipment capable of receiving, transmitting and processing multiplexed frames. It may, for example, be calculators, sensors or actuators. It will be noted that the network R could comprise several (at least two) buses interconnected via a communicating (electronic) organ, for example an intelligent service box (or BSI). Note also that the number of organs (communicating) Oi connected to the bus B may be different from five, since it is at least two.

In the nonlimiting example illustrated, each (communicating) element Oi is equipped with a coding device D1 according to the invention and a corresponding first or second decoding device D2 according to the invention. Therefore, it is considered here, by way of purely illustrative example, that each organ Oi is capable of transmitting multiplexed frames on the network R and of receiving multiplexed frames of this same network R. But, an organ Oi may comprise only a coding device D1, for example if it does not need to use or receive binary numbers, or a first or second decoding device D2, for example if it does not produce or not to transmit binary numbers.

A coding device D1, according to the invention, is arranged to code NB binary numbers (of the aforementioned type) for a (communicating) element Oi, so that they can be transmitted in the form of pairs of coded binary numbers C1 and C2. For this purpose, the coding device D1 occurs whenever its organ Oi wants to transmit on the network R a binary number NB via a total number of bits which is less than N1 and function of a chosen precision. When such a situation occurs, the coding device D1 constitutes, on the one hand, a first coded binary number C1 of N2 bits from a bit string which is extracted from the sequence of N1 bits of the number NB considered. , and, secondly, a second coded binary number C2 which characterizes the positioning in the sequence of N1 bits (of the number NB considered) of the bit string extracted (which participates in the constitution of Cl), so that these first C1 and second C2 coded bits are transmitted in place of the binary number NB considered.

The coding method proposed here is based on the use of the properties of a scientific notation of the type "sign, mantissa and exponent" in which the chosen precision is carried by the mantissa and the order of magnitude by the exponent. It is recalled that in scientific notation a decimal number x can be defined by the expression x = +/- a * Bn, where a is the mantissa, B the chosen base (for example B = 10), and n is exhibitor. The number N2 of bits of a first coded binary number C1 is determined by the precision that is desired. This number N2 is thus chosen so that a value coded in binary on N2 + 1 bits and starting with a first bit (left) of value equal to one (1) has a precision at least equal to the desired accuracy. For example, if one wants a precision higher than or equal to 1%, one must have 112112N2 0,01, which imposes a number N2 equal to 6 (indeed, 1/27 = 1/128 0,0078 (< 0.01), while 1/26 = 1/64 0.0156 (> 0.01)). Note that the factor 1/2 in the expression 1/2 * 1 / 2N2 0.01 results from the fact that if a rounding is made to the nearest value (higher or lower) then the maximum error corresponds to 1 / 2 bit. The number Nmax of bits defining a second coded binary number C2 is set by the maximum decimal number which is necessary to encode the maximum value Vmax of a parameter taking into account the chosen precision. For example, if the maximum value Vmax of a parameter is equal to 30000, it takes 18 bits to represent it in binary notation (in base two), and only 10 bits to represent it in a coded way (according to the invention) with a precision greater than or equal to 1%, as will be seen below. However, to define the decimal number 10, it takes four bits (more precisely 1010). Therefore, in this example the number Nmax of bits necessary for the definition of the decimal number 30000 is equal to 4 (ie Nmax = 4). The above is valid when Vmin is different from zero (0). If it is desired to encode values within a range that includes the value zero (0), the value Vmin is then the lowest value for which the target accuracy (calculated in%) is reached. For values between 0 and Vmin, the accuracy in absolute value will be equal to the value corresponding to '/ 2 bit of the first coded bit number C1, and the second coded bit C2 is 0000 for these values between 0 and Vmin.

At least two embodiments may be envisaged for carrying out the coding according to the invention. In a first embodiment, the coding device D1 builds the first coded bit number C1 by deleting at least a portion of the zero value bits (0) which are located before the first bit of value equal to one (1) of the following N1 bits, and a possible part of the bits of the sequence of N1 bits of the number NB considered which are located from the last bit of the latter (NB), so that it remains in the end a chain of N2 bits .

This first embodiment is particularly adapted to the case where the minimum value Vmin that can take the number NB is zero. Note that in this first embodiment, the maximum number NS of zero-value bits (0) of high order, which can be deleted from a sequence of N1 bits of a number NB, is at most equal to N1- N2.

Moreover, in this first embodiment, the maximum number Ni, of least significant bits, which can be deleted from a sequence of N1 bits of a number NB, is at most equal to N1-N2. Indeed, if we can remove the N1 - N2 bits of the highest weight of a sequence of N1 bits, we can no longer remove bits of least weight, and if the most significant bit of a After N1 bits has a value equal to one, the N1 - N2 bits with the lowest weights must be removed. It will also be noted that in this first embodiment the second coded bit number C2 can characterize the positioning in the sequence of N1 bits of the number NB or the least significant bit of the bit string extracted which is constituted by the non-bits. removed from the sequence of N1 bits of the number NB, or the most significant bit of the bit string extracted which is constituted by the non-deleted bits of the sequence of N1 bits of the number NB. For example, if N2 is equal to 6 and the binary number NB is defined by the ordered sequence of N1 bits 000110111001 (here N1 = 12), then the operation of removing the most significant bits (on the left) ends. to the intermediate chain of Nr remaining bits 110111001 (suppression of 000 on the left - here Nr = 9 (12 - 3)). We must therefore remove Nr - N2 bits of the intermediate chain among its least significant bits (right), here 3 bits. Nd denotes the result of the difference Nr - N2. We then arrive at the N2 bit chain 110111 extracted from the ordered sequence of N1 bits of the binary number NB (suppression of 001 on the left). The first coded binary number Cl is therefore here wholly defined by the extracted N2 bit string (110111).

If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the bit string extracted, then it is defined by the sequence of four bits which represents the decimal value Nd (here equal to 3), ie C2 = 0011.

If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the bit string extracted, then it is defined by the sequence of four bits which represents the value 8, namely C2 = 1000. For example, if N2 is equal to 6 and the binary number NB is defined by the ordered sequence of N1 bits 000000011100 (here N1 = 12), then the operation of deleting the bits with the highest weight (at left) leads to the intermediate chain of Nr remaining bits 011100 (deletion of 000000 on the left because we can not remove more than N1 - N2 bits - here Nr = 6 (12 - 6)). We then have Nd = 0 (Nr - N2 = 6 - 6 = 0). Therefore, no other bit must be removed from the intermediate chain, so that it constitutes the N2 bit string 011100 extracted from the ordered sequence of N1 bits of the binary number NB. The first coded binary number C1 is therefore here wholly defined by the extracted N2 bit string (011100). If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the bit string extracted, then it is defined by the sequence of four bits which represents the decimal value Nd (here equal to 0), ie C2 = 0000. If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the bit string extracted, then it is defined by following four bits which represents the value 5, ie C2 = 0101. In a second embodiment, the coding device D1 builds the first coded bit number C1 by first deleting all the zero-valued bits which are located before the first bit of value equal to one (1) of the sequence of N1 bits, and this first bit having a value equal to one (1). Then, the coding device D1 determines the value Nd equal to N2 - Nr, where Nr is equal to the number of bits remaining in the sequence of N1 bits of the number NB after the deletion (by the left). Then, the coding device D1 constitutes the first coded bit number C1 which corresponds to this binary number NB as a function of the value of Nd. More precisely, if the value Nd is positive (and the minimum value Vmin is equal to zero and therefore N2 can be greater than Nr), then the coding device D1 adds to the Nr bits, remaining in the binary number NB after the deletion by the left, a number of bits equal to INdI (absolute value function), after the last of these Nr remaining bits (that is to say after the one which is the most right), in order to constitute the first number coded binary C1. The second coded binary number C2 then characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the first coded binary number C1. For example, if N2 is equal to 6, then the binary number NB is defined by the ordered sequence of N1 bits 000000011100 (here N1 = 12) and the minimum value Vmin is equal to zero, then the bit deletion operation of the strongest weight on the left (all those of null value and the first of value equal to 1) results in the string extracted from Nr remaining bits 1100 (deletion of 00000001 on the left Nr = 4 (12 - 8)). We then have Nd = 2 (N2 - Nr = 6 - 4 = 2). Therefore, two bits of zero value (0) must be added to the retrieved string before its first (least significant) bit. The first coded bit number C1 is here defined by the N2 bit string (110000). The second coded binary number C2 characterizing the positioning in the sequence of N1 bits of the number NB of the most significant bit of the first coded binary number C1, is defined by the sequence of four bits which represents the value 3, ie C2 = 0011.

If the value Nd is negative (and the minimum value Vmin is different from zero or equal to zero - the two cases are indeed conceivable here), then the coding device D1 deletes Nr bits, remaining in the binary number NB after the deletion by the left, a number of bits equal to INdI (function absolute value), starting from the last of these Nr remaining bits (that is to say the one which is the most right), in order to constitute the first coded binary number C1. The second coded binary number C2 then characterizes the positioning in the sequence of N1 bits of the number NB that is the most significant bit of the first coded bit number C1 (if the minimum value Vmin is different from zero or else equal to zero - the two cases are indeed conceivable here), or the least significant bit of the first coded bit number C1 (only if the minimum value Vmin is different from zero).

Note that if a parameter can in principle only take values between Vmin and Vmax, where Vmin is different from zero, then Nr is always greater than or equal to N2, and then all values that could be zero are coded to zero. be between 0 and Vmin. For example, if N2 is equal to 6 and the binary number NB is defined by the ordered sequence of N1 bits 001000011100 (here N1 = 12), then the operation of removing the most significant bits (on the left all those of zero value and the first of value equal to 1) results in the intermediate chain of Nr remaining bits 000011100 (deletion of 001 on the left Nr = 9 (12 - 3)). We then have Nd = -3 (N2 - Nr = 6 - 9 = -3). Therefore, three bits must be removed from the intermediate string from its first (least significant) bit. After this 3-bit deletion we obtain the string extracted from N2 bits 000011 (deletion of 100 by the right). The first coded bit number C1 is here defined by the string extracted from N2 bits (000011). The second coded binary number C2 can then either characterize the positioning in the sequence of N1 bits of the number NB of the most significant bit of the first coded binary number C1, and in this case C 2 is defined by the following four bits which represents the value 8, ie C2 = 1000, or characterize the positioning in the sequence of N1 bits of the number NB of the least significant bit of the first coded bit number C1, and in this case C2 is defined by the sequence of four bits which represents the value 3, ie C2 = 0011. If the value Nd is zero (and the minimum value Vmin is other than zero or equal to zero - the two cases are indeed conceivable here), then the coding device D1 constitutes the first coded bit C1 with the Nr bits remaining in the sequence of N1 bits of the number NB after the deletion by the left. The second coded binary number C2 then characterizes the positioning in the sequence of N1 bits of the number NB either of the most significant bit of the first coded bit C1 or of the least significant bit of the first coded bit C1. For example, if N2 is equal to 6 and the binary number NB is defined by the ordered sequence of N1 bits 000001011100 (here N1 = 12), then the operation of removing the most significant bits (on the left all those of zero value and the first of value equal to 1) results in the string extracted from Nr remaining bits 011100 (deletion of 000001 on the left Nr = 6 (12 - 6)). We then have Nd = 0 (N2 - Nr = 6 - 6 = 0). Therefore, the first coded bit number C1 is here defined by the string extracted from N2 bits (011100). The second coded binary number C2 can then either characterize the positioning in the sequence of N1 bits of the number NB of the most significant bit of the first coded bit number C1, and in this case C2 is defined by the following four bits which represents the value 5, ie C2 = 0101, or characterize the positioning in the sequence of N1 bits of the number NB of the least significant bit of the first coded binary number C1, and in this case C2 is defined by the sequence of four bits which represents the value 0 or C2 = 0000. It will be noted that in order to limit as much as possible the number of bits N2 of a first coded binary number C1, corresponding to a binary number NB representative of the value V of a parameter, this first coded binary number C1 can be representative of this value V divided by the minimum value Vmin that this parameter can take (ie V / Vmin), provided that the minimum value Vmin is non-zero. For example, if a parameter can take values between 10 (Vmin) and 30000 (Vmax), then the ratios V / 10 will be coded according to the invention. It will also be noted that when the values of a parameter can be positive or negative, a bit dedicated to the sign of the coded decimal number must be provided in the coding (either in Cl or in C2 or in a separate dedicated bit). It will also be noted that the coding device D1 is preferably implemented in the form of software (or computer) modules stored in a memory (or the like) of an organ Oi. But, it could also be realized in the form of electronic circuits, or a combination of electronic circuits and software modules. In order to be able to decode the first C1 and second C2 coded binary numbers obtained with one or the other of the two embodiments of a coding device D1, the invention proposes two decoding devices D2. The first decoding device D2 is used when the coding device D1 is of the type of the first embodiment (deletion of zero value bits to the left), while the second decoding device D2 is used when the coding device D1 is of the type of the second embodiment (deletion of the zero value bits and the first value bit equal to 1 on the left). When the first decoding device D2 receives first C1 and second C2 coded bits, each consisting of an ordered sequence of bits between a first bit of highest weight and a last bit of least significant bit, it performs two operations. . A first operation (i) consists in constituting a field of N1 bits whose values are all zero (0).

A second operation (ii) consists in replacing bits of this field with the bits of the first coded binary number C1. Two implementations can then be envisaged depending on whether the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the bit string extracted, or that it characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the bit string extracted forming C1. If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the extracted bitchain C1, then the second operation (ii) consists in replacing bits of the N1 field. bits by the bits of the first coded bit C1 starting with the least significant bit whose weight within the field is equal to the decimal value defined by the second coded bit C2. The binary number NB, which was represented by the first C1 and second C2 coded bits, is then constituted by the ordered sequence of N1 bits of the field after the replacement. For example, if the first coded bit number C1 is defined by the N2 bit string 110111 and the second coded bit number C2 is subsequently defined by four bits 0011 which represents the decimal value 3, then the last bit of C1 (lowest weight) must replace in the field of N1 initial bit (000000000000) its weight bit equal to the decimal value 3. Therefore, after replacing the bits of Cl in the field, we obtain the binary number NB 000110111000 For comparison, the initial NB number, that is to say before coding, was equal to 0001 1 01 1 1 001. If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the bit of highest weight of the extracted bitstream forming C1, then the second operation (ii) consists in replacing bits of the N1 bit field by the bits of the first coded bit number C1 starting with the most significant bit of which the weight within the field is equal to the decimal value defined by the second coded binary number C2. The binary number NB, which was represented by the first C1 and second C2 coded bits, is then constituted by the ordered sequence of N1 bits of the field after the replacement.

For example, if the first coded bit number C1 is defined by the N2 bit string 110111 and the second coded bit number C2 is subsequently defined by four bits 1000 which represents the decimal value 8, then the first bit of C1 (most significant weight) must replace in the field of N1 initial bit (000000000000) its weight bit equal to the decimal value 8. Therefore, after replacing the bits of Cl in the field, we obtain the binary number NB 000110111000 For comparison, the initial NB number, i.e., before coding, was equal to 0001 1 01 1 1 001. When a second decoding device D2 receives first C1 and second C2 coded bits, each consisting of an ordered sequence of bits between a first bit of highest weight and a last bit of least significant weight, it performs three operations. A first operation (i) consists in constituting a field of N1 bits whose values are all zero (0). A second operation (ii) consists in replacing bits of this field with the bits of the first coded binary number C1. Again two implementations can then be envisaged depending on whether the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number. NB of the least significant bit of the extracted bit chain C1, or that it characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the extracted bit string forming C1. If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the extracted bitchain C1, then the second operation (ii) consists in replacing bits of the N1 field. bits by the bits of the first coded bit C1 starting with the least significant bit whose weight within the field is equal to the decimal value defined by the second coded bit C2.

If the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of the bit string extracted forming C1, then the second operation (ii) consists in replacing bits of the field of N1 bits by the bits of the first coded bit number C1 beginning with the most significant bit whose weight within the field is equal to the decimal value defined by the second coded bit number C2. A third operation (iii) consists in replacing by a bit of value equal to one (1) the bit of the field which is situated just before (on the left) that which has been replaced by the first most significant bit of the first number. coded binary C1.

The binary number NB, which was represented by the first C1 and second C2 coded bits, is then constituted by the ordered sequence of N1 bits of the field after the double replacement. For example, if the first coded bit number C1 is defined by the N2 bit string 110111, then the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the most significant bit of C1, and that the second coded binary number C2 is subsequently defined as four bits 1000 which represents the decimal value 8, then the first bit of Cl (of highest weight) must replace in the field of N1 initial bits (000000000000) its bit of weight equal to the decimal value 8. Therefore, after replacing the bits of Cl in the field, the latter is constituted by the chain of N1 bits 000110111000. Then, we replace with a bit of value equal to one (1) the bit of the field which is located just before that which has been replaced by the first most significant bit of the first coded binary number Cl. We then obtain the binary number NB 001110111000. For comparison, the initial NB number is to say before coding, was equal to 00 For example, if the first coded bit number C1 is defined by the N2 bit string 110111, then the coded binary number C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of Cl, and that the second coded bit number C2 is subsequently defined by four bits 0011 which represents the decimal value 3, then the first bit of Cl (of highest weight) must replace in the initial N1 bit field (000000000000) its bit of weight equal to the decimal value 3. Therefore, after replacing the bits of Cl in the field, the latter is constituted by the N1 bit string 000110111000. Then, we replace with a bit of value equal to one (1 ) the bit of the field which is situated just before the one which has been replaced by the first most significant bit of the first coded binary number Cl. We then obtain the binary number NB 001110111000. For comparison, the initial NB number, c ' ie before coding, was equal to 001110111001. It will be noted that the first decoding device D2, the variant of the first decoding device D2, the second decoding device D2 and the variant of the second decoding device D2 are preferably made in the form of software modules (or computer) stored in a memory (or the like) of an organ Oi. But, they could also be made in the form of electronic circuits, or a combination of electronic circuits and software modules.

The invention is particularly advantageous because it allows to significantly reduce, by coding in the form of a pair of coded bits, the number of bits that define a binary number to be known with a chosen precision. By way of example, the invention now makes it possible to code on 10 bits (6 bits for C1 and four bits for C2) with a precision greater than 1% (in fact greater than or equal to about 0.78%). which parameter value is between 10 and 665000, whereas in a conventional network, 18 bits are needed to define with the same precision any parameter value between 10 and 30000.

The invention is not limited to the embodiments of coding device, decoding device, communicating organ and vehicle described above, only by way of example, but it encompasses all the variants that may be envisaged. skilled in the art within the scope of the claims below.

Claims (13)

REVENDICATIONS1. Encoding device (D1) for a communicating member (Oi) capable of transmitting in a multiplexed communication network (R) binary numbers representative of values of at least one parameter between minimum values Vmin and maximum Vmax, characterized in that it is arranged, in the presence of a binary number NB, consisting of a sequence of NI bits ordered between a first bit of the strongest weight and a last bit of the least significant weight, and to be transmitted via a total number of bits less than NI and function of a precision chosen, to constitute, on the one hand, a first coded binary number C1 of N2 bits from a bit string extracted from said sequence of NI bits of the number NB , and, secondly, a second coded bit number C2 which characterizes the positioning in said sequence of NI bits 15 of the number NB of said extracted bit string, so that these first C1 and second C2 coded bits are transmitted to the place of said n NB binary shadow. 2. Device according to claim 1, characterized in that it is arranged to build said first coded bit number C1 by deleting at least a portion of the zero value bits which are located before the first bit of value equal to one of said a portion of NI bits, this part comprising a number NS of bits at most equal to NI-N2, and a part of the bits of said sequence of NI bits which are located from its last bit, so that it remains a string of N2 bits, this part having a number N 's of 25 bits at most equal to NI - N2. 3. Device according to claim 2, characterized in that said second coded bit C2 characterizes the positioning in the sequence of N1 bits of the number NB of the least significant bit of the bit string extracted which is constituted by the bits removed from the NI bit sequence of the NB number. 4. Device according to claim 2, characterized in that said second coded bit C2 characterizes the positioning in the sequence of Ni bits of the number NB of the most significant bit of the bitsextraite string which is constituted by the bits not deleted. of the sequence of NI bits of the number NB. 5. Device according to claim 1, characterized in that it is arranged, in the presence of a minimum value V min equal to zero, to build said first coded binary number C1 by deleting all the zero value bits which are located before the first bit of value equal to one of said sequence of NI bits, and this first bit having a value equal to one, then to determine a value Nd equal to N2 - Nr, where Nr is equal to the number of bits remaining in said sequence of NI bits of the number NB after the deletion, then io either to delete a number of bits equal to INdI starting from the last of the Nr bits remaining in said binary number NB after the deletion, if this value Nd is negative, in order to constitute said first coded bit number C1, or to add a number equal to INdI of zero value bits after the last of the remaining Nr bits in said sequence of NI bits of the number NB after the deletion, if the value Nd is positive, in order to constituting said first coded bit number C1, again to constitute the first coded bit number C1 with the remaining Nr bits in said sequence of N1 bits of the number NB if the value Nd is zero, and in that said second coded bit number C2 characterizes positioning in the sequence of Ni bits of the number NB 20 of the most significant bit of said first coded bit number C1. 6. Device according to claim 1, characterized in that it is arranged, in the presence of a minimum value Vm; ,, different from zero, to build said first coded binary number C1 by removing all bits of zero value which are located before the first bit of value equal to one of said sequence of Ni bits, and this first bit having a value equal to one, then to determine a value Nd equal to N2 - Nr, where Nr is equal to the number of bits remaining in said sequence of N1 bits of the number NB after the deletion, then either to delete a number of bits equal to INd 'starting from the last of the Nr bits remaining in said binary number NB after the deletion, if this value 30 Nd is negative in order to constitute said first coded bit number C1, or to constitute the first coded bit number C1 with the remaining Nr bits in said sequence of NI bits of the number NB if the value Nd is zero, and in that said second coded bit number C2 c characterizes the positioning in the sequence of N1 bits of the number NB of the least significant or least significant bit of said first coded bit number C1. 7. Device according to one of claims 1 and 6, characterized in that it is arranged to constitute first C1 and second C2 coded binary numbers representative of binary numbers each equal to the current value of a parameter divided by the minimum value Vm; n that can be taken when this parameter is non-zero. 8. A decoding device (D2) for a communicating member (Oi) suitable for receiving from a multiplexed communication network (R) the first and second C2 coded binary numbers coded by a coding device (D1) according to one of claims 1 to 3 and representative of binary numbers NB to be reconstituted and consisting of a sequence of NI bits, characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of NI bits of a number NB and each consisting of an ordered sequence of bits between a first bit of highest weight and a last bit of least significant weight, i) to form a field of Ni bits whose values are all nil, then ii) to replace bits of this field with the bits of said first coded bit number C1 beginning with the least significant bit whose weight within the field is equal to said decimal value defined by said second number coded binary C2, so reconstructing an NI bit string representative of said NB binary number with a selected precision. 9. Decoding device (D2) for a communicating member (Oi) able to receive from a multiplexed communication network (R) the first 25 C1 and second C2 binary numbers coded by a coding device (D1) according to one of Claims 1, 2 and 4 and representative of binary numbers NB to be reconstituted and consisting of a sequence of NI bits, characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence N1 bits of a number NB and each consisting of an ordered sequence of bits between a first bit of highest weight and a last bit of least significant weight, i) to constitute a field of NI bits whose values are all nil, then ii) to replace bits of this field with the bits of said first coded bit number C1 beginning with the most significant bit whose weight within the field is equal to said decimal value defined by said second number coded binary C2, in order to reconstructing an NI bit string representative of said NB binary number with a selected precision. s 10. Decoding device (D2) for a communicating member (Oi) adapted to receive from a multiplexed communication network (R) the first C1 and second C2 binary numbers encoded by a coding device (D1) according to one of the Claims 1 and 5 and representative of binary numbers NB to be reconstituted and consisting of a sequence of NI bits, characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of NI bits of a number NB and each consisting of an ordered sequence of bits between a first bit of highest weight and a last bit of least significant weight, i) to form a field of NI bits whose values are all zero then ii) to replace bits of this field 15 with the bits of said first coded bit number C1 beginning with the most significant bit whose weight within the field is equal to said decimal value defined by said second binary number coded C2, and iii) p to replace by a bit of value equal to one the bit of this field which is located just before that which has been replaced by the first most significant bit of said first coded first bit C1, in order to reconstruct a string of N1 bits representative of said NB binary number with a selected precision. 11. Decoding device (D2) for a communicating member (Oi) able to receive from a multiplexed communication network (R) the first C1 and second C2 binary numbers encoded by a coding device (D1) 25 according to one Claims 1, 6 and 7 and representative of binary numbers NB to be reconstituted and consisting of a sequence of N1 bits, characterized in that it is arranged, in the presence of first C1 and second C2 coded binary numbers representative of a sequence of NI bits of a number NB and each consisting of an ordered sequence of bits between a first bit of highest weight 30 and a last bit of least significant weight, i) to constitute a field of NI bits whose values are all nil, then ii) to replace bits of this field with the bits of said first coded bit number C1 beginning with the least significant bit whose weight within the field is equal to said decimal value defined by said second number coded binary C2, and ii i) to replace by a bit of value equal to one the bit of this field which is located just before that which has been replaced by the first most significant bit of said first coded bit number C1, in order to reconstruct a string of NI bits representative of said NB binary number with a chosen precision. Communicating organ (Oi) adapted to be connected to a multiplexed communication network (R) for receiving and / or transmitting binary numbers, characterized in that it comprises a coding device (D1) according to one of the claims. 1 to 7 and / or a decoding device (D2) according to one of claims 8, 9, 10 or 11. 13. Vehicle comprising at least one multiplexed communication network (R), characterized in that it further comprises at least two communicating members (Oi) according to claim 12, connected to said multiplexed communication network (R).