FR2653281A1 - Line interface for an information transmission network - Google Patents

Abstract

Line interface for an information transmission network including a filter 1, having two input terminals (e1, e2) connected to information transmission wires and two outputs (s1, and s2), characterised in that the filter consists of an input stage (11 or 12) associated with each input (e1 e2) and of a bandpass filter (13, 14) between the input stage and the output, this bandpass filter including a resistor (R4) mounted in parallel with the capacitor (C2) mounted in series.

Description

The present invention relates to a line interface for an information transmission network, comprising a filter having two input terminals connected to information transmission wires and two outputs.

Multiplex information transmission networks for vehicles are known.

Each subsystem or station having to communicate is connected to the network bus graciated to a line interface circuit. The purpose of this line interface is to provide the link between the network bus constituted by wires and a protocol manager associated with the station. It realizes the formatting of the logic signals from the protocol manager in a compatible form of the bus (analog signals).

Patent 2,627,036 describes an interface connecting a station to the bifurcated bus and having a filter.

The purpose of the present invention is to provide a filter having a low dynamic impedance with respect to the common mode. This impedance must be close to the characteristic impedance of the line vis-à-vis the common mode in order to avoid resonances. This filter improves the immunity of the line transmitter / receiver to the common mode and the differential mode. It introduces a rate-compatible delay for a variable number of stations connected to the network. It can be realized in the form of a monolithic component
The modification of the input stage structure (R1 N C1) as a low-pass filter makes it possible to improve immunity with respect to high frequencies (in particular for compatibility with electromagnetic radiation.

According to one characteristic, the filter consists of an input stage associated with each input (e1 e2) and a bandpass filter between the input stage and the output, this bandpass filter comprising a resistance mounted in parallel with the capacitor mounts in series.

The addition of a resistor significantly improves the immunity of the device in the bandwidth of the filter without significantly degrading the propagation time.

The addition of the resistor allows the suppression of the reset of the comparator necessary for the initialization of the receiver.

The invention will now be described in more detail with reference to an embodiment given by way of example and shown in the accompanying drawings in which - Figure i is a diagram of the interface.

- Figure 2 is a detailed view of the filter.

The interface according to the invention comprises a filter 1 whose input terminals and and ee are connected to data transmission son of information 2 and 3 (bus).

The filter is connected to the output of a bias amplifier 4 delivering a bias voltage to the filter.

The outputs S1 and S2 of this filter are respectively connected to the non-inverting and inverting inputs of a first comparator whose output is connected to the protocol handler 9. The output sX is also connected to a non-inverting input of a second comparator 7 whose other input, that is to say its inverting input, is connected to the output of the bias amplifier so as to be at the bias potential delivered
The output is connected to a non-inverting input of a third comparator 8 whose other input, that is to say its non-inverting input, is connected to the output of the polarization amplifier.
The outputs of these comparators 7N 8 are directly connected to the protocol handler 9
The filter I consists of separate but related parts at the level of optimization of the set - The input stage 11 or 12 having as input e1 or e @, - the bandpass 13 or 14 with limited attenuation in
the low frequencies connected to the input stage 11
or 12 respectively. The outputs of the band-pass
13 and 14 are marked s1 and s2 respectively.

The input stage 11 or 13 constitutes RI and C1 determines the immunity with respect to electromagnetic radiation. Its function is to limit the energy and the amplitude of the high frequency signals resulting from electromagnetic coupling and to protect the following stages.

The resistor R1 behaves as a pseudo impedance matching of the line in dynamic mode vis-à-vis the common mode. The value of R1 must be chosen in the interval 5ti Q - 180 #. The value of the Cl capacitance determines the immunity to electromagnetic radiation The higher the value of the capacitance, the better the immunity and the greater the propagation time.

The bandpass filter 13 or 14 of the Wien Bridge type completes the filtering performed by the input stage. Its function is to improve the immunity, to make the propagation time quasi independent of the load of the bus and staff to overcome variations in the differential voltage of the bus.

Each bandpass filter 13 or 14 consists of a resistor R2 and a capacitor C2 connected in series, a resistor R3 connected to the resistor R3 of the other filter and a capacitor C3 connected to the capacitor C3 of the other filter.
In order to take into account the output impedance of 1 input stage of the I-line receiver, the values must be chosen with the following restrictions: # <R2, R3 <22 K #
68 pF: C2, C3
For collision mode operation, the propagation delay that penalizes transmission is the propagation time corresponding to the transition from the dominant state to the recessive state (D -> R).

The recessive state is characterized by a current I rec of Smfd supplied by each station connected to the bus. The Irec current will therefore be located at each station for the passage (D -> R).

By way of example, during the transient phase (D -> R), N has on each data wire
Irec = dV
C1 dt for Irec = 1 mA and C1 = 220 pF: dv = 4.5 V / s
dt
The dv parameter optimizes the band
passing through the WIEN bridge whose central frequency is F cent = t with R2 = R2 and C2 = C3 2. #. R2.C2
For a sinusoldal signal U, AMPLitude = 1.5 v of frequency F: dv max = 2. #. F.AMPL =
dt either F cent = 447 KHz, of o R2 = R3 = 3.3 K #
C2 = C3 = 100 pF
The law giving the values R2, C2 is given by
Trrc =
C1 R2.C2
A resistor R4 is connected in parallel with the capacitor C2 in series between 1 input and the output.

Resistance R4 serves to improve the immunity in the passband of the filter and to avoid initialization of the receiver.

The lower the value of the R4 resistance, the better the immunity and the higher the propagation time,
A compromise consists in choosing R4 with respect to R2 =
R3 in the range 5.R2 R4 <20.R2. As an indication a suitable value of R4 is 27K # to 33K #, or 39 to 56K # or 56 to 68K #

Claims (1)

CLAIMS 1) line interface for an information transmission network comprising a filter (L) having two input terminals (el, ee) connected to information transmission wires and two outputs (s1, and s2), characterized in that the filter comprises an input stage (11 or 12) associated with each input (e1 ee) and a bandpass filter (13, 14) between the input stage and the output, this bandpass filter comprising a resistor (R4) connected in parallel with the capacitor (C2) connected in series, 20) Interface according to claim 1, characterized in that the input stage consists of a resistor (R1) and a capacitor (C1). 30) Interface according to any one of  preceding claims, characterized by the  that the Band-pass bandpass filter  Wien consists of a resistance R2 and a  capacitor that in sense and d t a resistance  R3 and a capacitor C3.