EP2845355A1 - Electronic control unit having a configurable line termination - Google Patents

Abstract

An electronic control unit (ECU_AUTO) having a configurable line termination for a digital communication network having at least two signal transmission lines (LH, LL), said electronic control unit comprising a line termination (RTA, RTB, CT) essentially defined by an equivalent termination resistance capable of connecting the signal transmission wires to each other, a line termination switching device (μC, SWH, SWL, BL2) for activating the line termination, characterised in that the electronic control unit further comprises a device (μC, Vref1, Vref2, SWPOL_H, SWPOL_L) for determining the presence of other line terminations on the communication network and for self-adapting to control the activation of the line termination on the basis of the presence or otherwise of other line terminations on the communication network.

Description

 T HE C O N E A T E R E C O M E L A T I N T I N T I N T I N T

LI G N E CON FI G U RABLE

The invention relates to an electronic control unit with line termination, as well as to a digital communication network comprising such an electronic control unit, allowing electrical equipment or subassemblies of electrical equipment, to communicate between them, with a reduced number of electrical wires. Such communications networks are used, for example, for applications in the field of automobiles, industrial installations, railways, the military or even consumer electronics.

 Some digital communication networks have line terminations designed to match the impedance of the network and comply with network topology rules. For example, the CAN HS communication network comprises two line terminations generally located on the furthest nodes of the network. FIG. 1 represents an exemplary topology of such a network. The bus line 10 interconnects several electronic control units ECU_A, ECU_B, ECU_C and ECU_D, two of which, ECU_A and ECU_B, are equipped with T line terminations, it being understood that said bus line can be composed of 1 wire or more.

FIG. 2 represents an electronic control unit 20 (ECU) with line termination, in the nonlimiting example of a 2-wire bus line. Such a unit comprises a computer 22 (μθ), for example a microcontroller, and a line termination 24 defined by a termination circuit, R _T A, RTB and CT, connected between the signal transmission wires CAN_H and CAN_L forming the bus line 10. Each termination can thus, for example, be integrated into a control unit present on the vehicle network. FIG. 3 represents a first example of application on a vehicle 30 comprising a communication network 32 with three electronic control units 34, 36 and 38, for example a Multifunction Motor Calculator (MMC), a Programmed Electro-Stabilizer (ESP) and an Intelligent Service Enclosure (BSI). In this first configuration, the two ends formed by the CMM and BSI units are equipped with a T-line termination.

FIG. 4 represents a second example of application on a vehicle 40 comprising a communication network 42 with four electronic control units 44, 46, 48 and 49. In addition to the three CMM, ESP and BSI units shown in FIG. network also includes a fourth Electric Parking Brake unit (ESF) generally arranged at the rear end of the vehicle. In this case, the line termination T integrated in the BSI unit in the example of Figure 3 can be advantageously moved in the FSE unit.

 To manage this diversity of positioning of line termination units, two types of solutions are traditionally used. The first solution is to manage diversity on the BSI unit, creating two variants with and without line termination. This first solution has the disadvantage of doubling the diversity of the BSI units compared to the existing diversity related to other factors, resulting in an additional cost in the management of diversity, the number of references at the edge of the assembly line and in spare parts.

The second solution, represented in FIG. 5, consists in managing the diversity by the use of a network configurable line termination electronic control unit 50, that is to say by integrating the termination components of the network. line 54 to the BSI unit and planning to connect them to CAN_H and CAN_L transmission wires not internally of the control unit 50 but via two additional pins 56a and 56b and a "bridge" 58 made by two additional wires. This second solution has the disadvantage of requiring the addition of two pins in the connection of the BSI unit, and the addition of a two-wire "bridge" in the wiring on the vehicles without FSE unit, generating extra cost due to the additional pins and wires.

 In EP 0 946 917 B1, an electronic bus system is disclosed for fixed or mobile applications, such as a CAN bus system for use in the automotive industry. The bus system comprises a bus line with at least two signal transmission wires and two ends, each being defined by a terminating resistor connecting the signal transmission wires to each other, and a plurality of electronic control units, which between the two ends are connected to the signal transmission wires and are adapted to transmit and receive electrical signals via the signal transmission wires. The line is divided into a plurality of sections, which are interconnected by means of connection circuits and form an annular unit. Each connection circuit comprises relay means by means of which each connection circuit is adapted, in coordination with the other connection circuits, for connecting at least one of the electronic control units to the signal transmission wires and / or for connecting to the least one terminating resistor to the signal transmission wires to define the ends of the bus line.

Such an annular topology electronic bus system makes it possible to disconnect a defective section of the annular unit and to redefine the new ends excluding the defective section by switching the termination resistors of the remaining sections according to the modified topology of the bus line. Such a system does not, however, adapt to different configuration of the bus line depending on the presence or absence of some electronic control units. In addition, such a system requires the use of a plurality of electronic control units provided with connecting circuit means communicating with each other to detect the malfunction or otherwise of a control unit. neighboring electronics. Such a solution is therefore restrictive in its applications and expensive in its implementation.

 The invention aims to overcome the drawbacks of the state of the art and in particular to provide a configurable line termination electronic control unit capable of adapting to different configurations of a digital communication network.

 To do this, it is proposed according to a first aspect of the invention, a configurable line termination electronic control unit for digital communication network to at least one transmission line formed of two signal transmission wires, said electronic control comprising a line termination essentially defined by an equivalent terminating resistor capable of connecting the signal transmission wires to each other, and characterized in that the electronic control unit further comprises a line termination switching device for enable line termination.

Such an electronic control unit allows the switching of the line termination if necessary. Thus, if the communication network includes the correct line terminations, the electronic control unit will command not to activate its termination, whereas if the communication network still requires line termination then the electronic control unit will control the termination of the line. activation of its termination. To determine the situation in terms of line termination, the control unit may be connected to a diagnostic tool, such as another digital communication network or a diagnostic line, so as to telecode the control unit by example according to the nomenclature of the vehicle. In addition, such an electronic control unit makes it possible to dispense with the diversity management of the electronic control units such as the BSI unit avoiding the additional costs incurred as well as the use of an electronic control unit equipped with pins. extra and "bridge" made by two additional son again avoiding the additional costs. According to an advantageous embodiment, the electronic control unit further comprises a device for determining the presence of other line terminations on the communication and self-adaptation network to control the activation of the line termination. depending on the presence or absence of other line terminations on the communication network. Such an electronic control unit makes it possible, on the one hand, to switch the line termination if necessary and, on the other hand, to determine the presence of other line terminations on the communication network in order to perform a self-service function. adaptation of the presence or absence of the line termination on said unit depending on the presence or absence of other line terminations. Thus, if the communication network includes the correct line terminations, the electronic control unit will command not to activate its termination, whereas if the communication network still requires line termination then the electronic control unit will control the termination of the line. activation of its termination. Such an electronic control unit, by virtue of its self-adaptation function, makes it possible to dispense with a configuration of telecoding switching requiring another communication network to communicate with the unit.

According to an advantageous embodiment, the device for determining the presence of other line terminations is a device for measuring a polarization magnitude of the communication network comprising two sources of a reference polarization magnitude, two bias for respectively connecting a source of a reference bias magnitude to the equipotential of the line termination and the other source of a reference bias magnitude to a signal transmission wire for biasing the communication network with adequate voltages, and means for measuring the polarization magnitude of the communication network to determine the situation in terms of line termination. Such a configurable line termination electronic control unit can thus measure a magnitude such as the bias voltage of the communication network to determine the network situation in terms of line termination present on the network.

 According to an advantageous variant, the measurement of the bias voltage is performed via an analog input of a calculation unit of the control unit. Such a measure is simple and inexpensive to implement.

 According to another embodiment, the configurable line termination electronic control unit further comprises a power source, and a power switch adapted to control the power supply of the other electronic control units of the communication network. The use of such a power device makes it possible to measure a magnitude of the communication network without mutual disturbance with the other electronic control units if they were fed during the measurement phase.

 According to another embodiment, the switching device comprises a first terminating switch located between a transmission wire and a first line terminating resistor, and a second terminating switch located between the other transmission wire and the resistor. line termination, and a calculation unit programmed to control the termination switches. Advantageously, the switching device further comprises a logic flip-flop between the computation unit and the termination switches. This makes it possible to mitigate a possible failure of the control unit during a critical phase such as the rolling of the vehicle in which it would be integrated and maintain a correct polarization of the network allowing the other control units to continue exchanging data. In the vehicle standby phases, the terminating switches will preferably be uncontrolled to reduce power consumption of the control unit.

According to a second aspect, the present invention relates to a digital communication network comprising at least two signal transmission wires, a plurality of electronic control units. connected to the signal transmission wires and adapted to transmit and receive electrical signals via said signal transmission wires, at least two line termination electronic control units of said plurality of electronic control units, each line termination being essentially defined by an equivalent terminating resistor connecting the signal transmission wires to each other, and of which at least one electronic control unit is a configurable line termination electronic control unit according to the first aspect of the invention. Such a communication network makes it possible to self-adapt the configurable line termination electronic control unit according to the termination situation of the network, such as the number of non-configurable line terminations present on the network. Alternatively, one could provide a communication network having a single bias resistor, the configurable line termination control unit should detect the presence or absence in the rest of the network.

 According to an advantageous embodiment, the digital communication network comprises at least one non-configurable line termination electronic control unit, and a single configurable line termination electronic control unit.

 According to a third aspect, the invention relates to a method of configuring the line terminations of a digital communication network equipped with at least one configurable line termination electronic control unit, the method comprising the steps of: ) determine the presence or absence of other line terminations in the communication network; (ii) self-adapting the impedance of the communication network by controlling the activation of the configurable line termination according to the presence or not of other line terminations.

According to an advantageous mode of implementation, the determination step consists of: (it) cutting the power supplies of the other units of electronic control of the network, (i2) closing the termination switches, and the polarization switches, (i3) measuring the magnitude of polarization and deriving the network situation in terms of termination, and the self-adaptation step consists in : (ii1) controlling the activation or not of the termination switches according to said situation.

Other features and advantages of the present invention will appear more clearly on reading the following detailed description of an embodiment of the invention given by way of non-limiting example and illustrated by the appended drawings, in which:

 FIG. 1 represents an exemplary topology of a communication network according to the prior art;

FIG. 2 represents a line-termination electronic control unit according to a first prior art;

FIG. 3 represents a first application of a communication network in an automobile according to the prior art;

FIG. 4 represents a second application of a communication network in an automobile according to the prior art;

- Figure 5 shows a line termination control unit according to a second prior art; - Figure 6 shows a communication network according to an embodiment of the present invention.

Referring to Figure 6, there is shown a communication network according to a preferred embodiment of the present invention. The communication network comprises at least one transmission line formed by two signal transmission wires L _H and L _L and a plurality of electronic control units ECUAUTO, ECUT-I, ECUT2, ECUs connected to the signal transmission wires. In the example shown, the network comprises an ECUAUTO configurable line termination electronic control unit, two control units electronic ECUn and ECUT2 non-configurable line termination according to two modes of implementation and a plurality of electronic control units ECUs without line termination. For non-configurable line termination control units, a first ECUn implementation consists in connecting in addition to a calculation unit μθτ-ι, two RT-IA and RT-I B resistors in series and a CTi capacitor between the equipotential between said two resistors in series and a reference potential. A second implementation ECUT2 consists in connecting a simple resistor RT ₂ between the two transmission wires L _L and L _H. There is also a LALIM power supply line for supplying with VALIM voltage all ECUn, ECUT2, ECUS electronic control units controlled via the ECUAUTO electronic control unit with configurable line termination, the voltage source VALIM being generally external to ECUAUTO- The ECUAUTO electronic control unit with configurable line termination comprises a computing unit μC which can be for example a microprocessor, a microcontroller, or any other equivalent device. This computing unit μC comprises a protocol manager of the multiplexed network as well as inputs / outputs for controlling the state of the network. The ECUAUTO control unit comprises a switch SWALIM controlled by an output of the calculation unit μθ, possibly via a logic latch BL1, thus allowing the ECUAUTO control unit to control the power supply of the other ECUn control units, ECUT2, ECUS of the network, and compensate for a possible failure of the ECUAUTO control unit during a rolling phase. In the standby phases of the vehicle, the switch SWALIM is preferably not controlled in order to reduce the consumption of the ECUAUTO control unit. The ECUAUTO control unit further comprises a non-volatile memory MNV and a transmitter / receiver. Multiplexed trunk E / R including in particular a data TX port to be transmitted and an RX port of received data. In this example, the switchable line termination of the network consists of the resistors RT _A and RT _B and the optional capacity CT. A switching device makes it possible to activate or not the line termination of the network. This switching device is formed for example by two switches SW _H and SW _L respectively connected to the transmission lines L _H and L _L and controlled by the calculation unit possibly via a flip-flop BL2.

In another implementation, with a switchable line termination consisting of a single resistor RT, the switching device for enabling or not the line termination of the network is then formed for example by a single switch SW _H or SW _L connected respectively to one of the transmission son L _H or L _L and controlled by the calculation unit possibly via a flip-flop BL2.

The control unit ECUAUTO further comprises a device for determining the presence of other line terminations on the network and self-adaptation to control the activation or not of its line termination according to the presence or not other line terminations. This determination and self-adaptation device comprises two polarization switches SW _PO L_H and SW _PO L_L controlled by the calculation unit possibly via a flip-flop BL3, to polarize the network, as well as two biasing voltages of reference V _ref. i and V _ref2 . The flip-flop BL3 makes it possible to alleviate a possible failure of the control unit ECU AUTO during a rolling phase and to maintain a correct polarization of the network allowing the other control units ECU-pi, ECUT2, ECUS to continue exchanging data. In the standby phases of the vehicle, the switches SW _PO L_H and SW _PO L_L are preferably not controlled in order to reduce the consumption of the ECUAUTO control unit. The voltage V _ref2 can be directly connected to ground. The analog input V _PO L of the calculation unit μC makes it possible to measure the bias voltage of the network for determining the network situation in terms of line termination of the network. We will now explain in more detail the principle of switching the line termination of the ECUAUTO configurable line termination control unit. As indicated above, the switching device of the line termination consists of a first switch SW _H located between the line L _H and the line termination resistor RTA, of a second switch SW _L located between the line L _L and the line termination resistor RTB and a command of the switches SW _H and SW _L by the calculation unit μC programmed for this purpose.

The SW _H and SW _L switches are controlled by the calculation unit μC as a function of the configuration with or without line termination required by the vehicle configuration, that is to say according to the presence or not of the good number line terminations. This command is carried out on the basis of a measurement of the polarization situation of the network by an integrated measuring device V _PO L in the computing unit μC. To compensate for a possible failure of the ECUAUTO control unit during a rolling phase and to maintain a correct polarization of the network allowing the other control units ECU-pi, ECUT2, ECUS to continue to exchange data, it is preferable to add the flip-flop BL2 between the command from the computation unit μC and the switches SW _H and SW _L. In the standby phases of the vehicle, the switches SW _H and SW _L will preferably be uncontrolled in order to reduce the consumption of the control unit ECUAUTO-

We will now explain in more detail the principle of determining the presence of other line terminations on the network and self-adaptation to control the activation of the line termination of the ECUAUTO control unit as a function of the presence or absence of other line terminations on the network. For this, the determination and self-adaptation device comprises a means for measuring a magnitude, for example a voltage V _PO L, of polarization of the communication network which makes it possible to detect the situation of the network in terms of termination, as for example, whether or not the network has the right number of line terminations, and thus to perform a self-adaptation function.

The device for measuring a bias voltage, as briefly mentioned above, comprises two sources of reference bias voltage V _ref i and V _ref2 , the second V _ref2 being the ground. The measuring device also comprises a first bias switch SW _PO L_H for forcing the reference bias voltage V _ref i the equipotential between the resistors RTA and RTB, and a second polarization switch SW _PO L_L to force the line L _L at the reference bias voltage V _ref2 . The polarization switches SW _PO L_H and SW _PO L_L are preferably controlled by the calculation unit μθ. The measurement of the bias voltage V _PO L is performed via an analog input of the calculation unit μθ connected to the line L _H. As already mentioned, a switching device of the power supplies (VALIM; SWALIM) of the other electronic control units ECU-pi, ECUT2, ECUS of the network allowing a measurement of the polarization of the network in the absence is also provided. disturbing voltage that can be generated by the other control units ECU-pi, ECUT2, ECUS if they were fed during the phase of said measurement and also avoiding disturbing the operation of said other electronic control units by the bias V _ref i and V _ref2 .

The calculation unit μC is programmed to determine the polarization situation of the network, so that the device for measuring a bias voltage can advantageously cut off the power supplies of the other electronic control units ECU-pi, ECUT2, ECU of the network, close the switches SW _H , SW _L , SW _PO L_H and SW _PO L_L, and measure the voltage V _PO L whose value makes it possible to deduce the situation of the network in terms of termination, ie the number of other units electronic controllers with line terminations, as explained below. In the example shown in FIG. 6, two examples of line terminations are shown, with or without a "common mode" CT capacitor in the middle point. To simplify the formulas below, they are understood without said common mode capacitor but those skilled in the art will be able to extend them to line terminations comprising this capacitor, for example considering that the resistance to be taken into account is the sum of the two resistors RTi _A and RTi _B on either side of said capacitor and that said capacitor has a negligible effect on the DC voltages implemented.

 For the case with only one other device of termination, one obtains:

Vpo _L = V _Ref1 ^* RT ₁ / (RT _{A +} RT ₁ )

For the case with two other termination devices, we obtain:

VPOL = V _REF1 ^* (RT-i // RT ₂ ) / (RT _A + (RT-i // RT ₂ )) ,.

 The voltage difference obtained according to the number of line terminations present enables the ECUAUTO configurable line termination electronic control unit to determine the number of these line terminations and to decide whether or not to switch the activation of its termination. line as needed to self-adapt to the communication network.

 For example, it may be decided to activate the configurable line termination when the number of terminations present on the network is equal to one, while the configurable line termination may be disabled when the number of line terminations is greater or equal to two.

It will be understood that various modifications and / or improvements obvious to those skilled in the art can be made to the various embodiments of the invention described in the present description without departing from the scope of the invention defined by the appended claims. For example, it will be understood that the present invention can be applied to different types of communication networks, especially to any network requiring the adaptation of the transmission line at two of its ends, such as CAN High Speed and FlexRay networks. As for the switches, it will be possible to use different technologies such as, for example, micro-relay, MOS or bipolar transistors.

Claims

R EV ENDI CAT IONS

1. A configurable line termination electronic control unit (ECUAUTO) for a digital communication network with at least two signal wires (L _H , L _L ), said electronic control unit comprising:

a line termination (RT _A , RT _B , CT) essentially defined by an equivalent termination resistor capable of connecting the signal transmission wires to each other,

characterized in that the electronic control unit further comprises:

- a switching device (μθ, SW _H , SW _L , BL2) line termination to activate the line termination.

A configurable line termination electronic control unit (ECUAUTO) according to claim 1, characterized in that it further comprises:

a determination device (μθ, V _ref i, V _REF2 , SW _PO L_H, SW _PO L_L) of the presence of other line terminations on the communication and self-adaptation network to control the activation of the line termination depending on the presence or absence of other line terminations on the communication network.

Configurable line termination electronic control unit (ECUAUTO) according to claim 2, characterized in that the device for determining the presence of other line terminations is a device for measuring a polarization quantity (V _PO L) of the communication network comprising:

two sources of a reference polarization magnitude (V _ref i,

V _re f2), two polarization switches (SW _PO L_H, SW _PO L_L) for respectively connecting a source of a reference bias quantity (V _ref i) to the equipotential of the line termination (RT _A , RT _B , CT ) and the other source of a reference bias quantity (V _ref2 ) to a signal transmission wire (L _L ) for biasing the communication network with adequate voltages, and

a means for measuring the polarization magnitude (V _PO L) of the communication network to determine the situation in terms of line termination.

Electronically controllable control unit (ECUAUTO) with configurable line termination according to Claim 3, characterized in that the measurement of the bias voltage (V _PO L) is performed via an analog input of a calculation unit (μθ). of the control unit.

Configurable line termination electronic control unit (ECUAUTO) according to one of claims 1 to 4, characterized in that it further comprises:

- a power source (VALIM),

- a power switch (SWALIM) able to control the power supply (ALIM) of the other electronic control units (ECU-pi, ECUT2, ECUS) of the communication network.

Configurable line termination electrical control unit (ECUAUTO) according to one of Claims 1 to 5, characterized in that the switching device comprises:

a first terminating switch (SW _H ) located between a transmission wire (L _H ) and a first line termination resistor (RTA), and a second terminating switch (SW _L ) located between the other transmission wire (L _L ) and the line termination resistor (RTB), and - a calculation unit (μθ) programmed to control the termination switches (SW _H , SW _L ).

Electrical configurable control unit (ECUAUTO) with configurable line termination according to claim 6, characterized in that the switching device further comprises a logic latch (BL2) between the calculation unit (μθ) and the termination switches. (SWH, SWL).

 8. Digital communication network comprising:

at least two signal transmission wires (L _H , L _L ),

a plurality of electronic control units (ECUAUTO, ECU-pi, ECUT2, ECUS) connected to the signal transmission wires and adapted to transmit and receive electrical signals via said signal transmission wires,

 at least two line termination electronic control units (ECUAUTO, ECUTI, ECUT2) among said plurality of electronic control units, each line termination being essentially defined by an equivalent termination resistance connecting the signal transmission wires between them, whose

at least one configurable line termination electronic control unit (ECUAUTO) according to one of claims 1 to 7.

A method of configuring line terminations of a digital communication network according to claim 8, equipped with at least one configurable line termination electronic control unit (ECUAUTO) according to one of claims 1 to 7, the method comprising the steps of:

- determine the presence or absence of other line terminations (ECUTI, ECUT2, ECUS) of the communication network; - self-adapting the impedance of the communication network by controlling the activation of the line termination (RT _A , RT _B , CT) configurable according to the presence or not of other line terminations.

 10. A method of configuring the line terminations of a digital communication network according to claim 9, characterized in that the determining step consists of:

 - cut the power supplies (ALIM) of the other electronic control units (ECU-pi, ECUT2, ECUS) of the network,

- close the termination switches (SW _H , SW _L ), and the polarization switches (SW _PO L_H, SW _PO L_L),

- measure the magnitude of polarization (V _PO L) and deduce the situation of the network in terms of line termination,

and characterized in that the self-adaptation step comprises:

- to control the activation or not of the termination switches (SW _H , SW _l ) as a function of the network situation in terms of line terminations detected on the network.