Title of Invention

TRANSCEIVER WITH ADJUSTABLE TERMINAL NETWORK FOR A CONTROL DEVICE

Abstract The invention relates to a transceiver for a control unit having a transceiver core for adapting the level of messages received or to be sent, an adjustable terminating network (5) being situated in the transceiver (1) that makes it possible to adjust at least two connection resistance values, the terminating network (5) and the transceiver core (2) being monolithically integrated in a semiconductor circuit.
Full Text

TRANSCEIVER HAVING AN ADJUSTABLE TERMINATING NETWORK FOR A
CONTROL DEVICE
The present invention relates to a transceiver for a control unit as recited in the preamble of Claim 1.
It is known that a plurality of function modules may be provided in a motor vehicle, where they are allocated to engine management or vehicle body electronics, for example, and special vehicle equipment such as a radio, car phone or navigation system. It is also known that the individual function modules may be connected to a bus system, e.g. a CAN bus, or: data exchange and for triggering, and a separate bus may be provided for each of the groups indicated above. The bus systems may be interconnected via a gateway for exchanging data and control commands. The function modules that require a high-speed data exchange, e.g., the control units for the engine and transmission, as well as other components that are essential for functionality and safety, are preferably connected to a so-called high-speed bus, and the less time-critical components, e.g., those that support special equipment, are connected to a so-called low-speed bus or comfort bus.
The function modules and/or control units include a controller and a transceiver, the main task of the transceiver being to create a physical interface with the bus system. The level of the messages received and/or to be sent is adjusted in the transceiver.
Since transmission rates in the bus systems are relatively high, reflection at the transition points must be reduced. In principle two different approaches are known here.

In decentralized termination, a terminating resistor [whose resistance is] equal to the characteristic impedance of the bus line is provided on both ends of the bus system, the two characteristic impedances being provided in the last control units at the end of the bus system. A typical value for the characteristic impedance is 120 Q for a twisted double line, for example. One problem with decentralized termination is that the design is not always known in advance. It is therefore also not known where the end of the bus system is located. In addition, with a star-shaped bus structure, there is no clearly discernible beginning and end.
Therefore, centralized termination is an alternative to decentralized termination. In centralized termination, the termination occurs centrally, e.g., in a control unit, typically with half the characteristic impedance being chosen as the terminating resistance. This is a reasonable compromise to minimize reflections centrally.
The two concepts for termination have in common the fact that the control units not involved in termination of the bus system are terminated using the highest possible resistance, e.g., in the kiloohm range.
The particular terminating resistors are provided together with elements of a supporting network and/or filters that 'may be necessary as discrete components on the transceiver. Owing to the fact that a central control unit may be a component of a centralized or decentralized termination or may not contribute to termination at all, the terminating resistor must be adapted, depending on the bus structure. This may be accomplished manually by replacing the resistors, or the same control unit may be manufactured in three variants having different terminating resistors, which is very complex and expensive.

DE 198 54 117 Al describes a circuit arrangement for communication with a plurality of electric components in a motor vehicle, including at least one bus for transmission of data between the components connected via network nodes and at least one terminating resistor, the at least one terminating resistor having an adjustable resistance value. The [resistance of the] terminating resistor is preferably adjusted electronically and is designed as a digital potentiometer, for example. In addition, it is proposed that all network nodes be allocated an adjustable terminating resistor. Depending on the type of adjustable resistors used, the adaptation of the total resistance may be accomplished in various ways. In a preferred exemplary embodiment, one of the network nodes analyzes the status messages of the other network nodes connected to the bus and automatically adjusts [the resistance of] its terminating resistor. The adjustment may advantageously also be accomplished automatically by an internal control unit on the bus which measures the total resistance and then adjusts the terminating resistances of all bus devices. Finally, the adjustment may also be performed by an external diagnostic device connected to the bus, either at the time of manufacture, e.g., after assembly of all function modules on a bus, or while being serviced in the shop for maintenance or for readjustment after installation or removal of modules. This allows simplifications in manufacturing and in subsequent modifications of motor vehicles, so that only a small number of control unit variants is required. When the adjustable resistors are integrated into the network nodes, separate assembly with terminating resistors is superfluous.
DE 100 20 142 Al describes a bus system including a bus structure to which electric components are connected, an error counter and a terminating resistor being assigned to the components, the terminating resistor being designed to be

adjustable and variable as a function of the error density detected by the error counter. The adjustable terminating resistor is preferably designed as a digital potentiometer and is situated in the electronic component.
Against the background of this related art, the technical object on which the present invention is based is to create a transceiver which simplifies termination on a bus system.
The technical object is achieved by the subject having the features of Claim 1. Additional advantageous embodiments of the present invention are derived from the subclaims.
The transceiver includes an adjustable terminating network by which at least two termination resistance values are adjustable, the terminating network and the t ransceiver core being monolithically integrated in a semiconductor circuit. The integration of the terminating network in the transceiver dispenses with separate resistors or potentiometers, which is of interest in particular with regard to cost and reliability because feeder lines are eliminated by the monolithic integration. Furthermore, the present invention utilizes the finding that a relatively continuous adjustment option is often not necessary. Instead, the option of switching between being unterminated and having centralized or decentralized termination is sufficient in most cases, adjustability of all three states being preferably provided, such an adjustability between two or three resistance values being very easily integrated into an IC-. Furthermore, this greatly simplifies the adjustment. The transceiver needs to be notified only once, e.g., by its assigned controller module, in which function the latter is installed. The controller then adjusts the particular resistance value (high resistance, characteristic impedance or half characteristic impedance).

In a preferred embodiment, the transceiver includes two terminals for connecting to a two-wire bus system such as CAN
or Flex Ray.
In another preferred embodiment, two first, second and third terminating resistors are connected in series between the terminals, the center taps of the series being electrically connected and the second and third terminating resistors being switchable on and/or off. The first two terminating resistors form the high-resistance unterminated terminal, coming into play when the other four resistors are switched off. The other four resistors preferably have the resistance values of the characteristic impedance of the line. Thus, if the two second terminating resistors are on, the transceiver is terminated with the characteristic impedance of the bus line, so the transceiver acts as a terminator of a decentralized termination. If the two third terminating resistors are then also on, the resulting terminating resistor is approximately equal to half the characteristic impedance, so the transceiver acts as a terminator of a centralized termination.
In another preferred embodiment, switches or fuses are associated with the terminating resistors. The advantage of these switches is the reversible setting of the resulting resistance value, but because of the design as an active component, this requires a permanent power supply to the transceiver module because the set termination resistance should not change. This problem may be solved by using fuses, but then the setting is irreversible.
In another preferred embodiment, the switches are designed as transistors.
In another preferred embodiment, a supporting network between the power supply voltage and ground is integrated into the

transceiver. This supporting network is connected to the center tap of the terminating resistors.
In another preferred embodiment, a filter is additionally integrated into the transceiver.
The present invention is explained in greater detail below on the basis of a preferred exemplary embodiment.
Figure 1 shows a transceiver having an integrated
terminating network with switches, and
Figure 2 shows a transceiver having an integrated
terminating network with fuses.
Transceiver 1 includes a transceiver core 2, a filter 3, a supporting network and a terminating network 5. Terminating
network 5 includes two first terminating resistors RTl, RT2 connected in series between two terminals BUSHIGH/ BUSLOW/ terminals BUSHIGH/ BUSLOW forming the interface to the bus lines. Two other terminating resistors RT3, RT4 and two third terminating resistors RT5, RT6 are provided in parallel with the first series connection of RTl, RT2, all the center taps of the series connection being interconnected via a common line VCM- In addition, a switch is associated with each terminating resistor RT3-RT6 of the second and third series connections. As indicated by the dashed line between the switches of terminating resistors RT3 and RT4 and/or RT5 and RT6, the switches of a series connection are always switched in the same sense, i.e., both switches are open or both are closed. Supporting network 4 includes two resistors RMCl and RMC2, which are connected in series and are situated between power supply voltage Vcc and ground GND. The center tap of the series connection of RMCl and RMC2 is connected to line VCM- In addition to the resistors described here, supporting network 4 may also contain capacitors, although they need not be

described in greater detail here. The main function of supporting network 4 is to support the recessive voltage level on the bus line. Filter 3 increases the interference resistance in the range of 15 to 25 MHz, The function of terminating network 5 is to adjust the suitable terminating resistance value, depending on the wiring of the transceiver, if necessary. The following cases are to be differentiated here, either transceiver 1 is not involved in the adjusted termination of the bus line, or transceiver 1 is part of the decentralized termination or terminates the bus line centrally.
In the first case, the four switches are opened so,that terminating resistors RT3-RT6 are uncoupled from terminals BUSHIGH, BUST,QW • In this case, only two terminating resistors RTl, RT2 which terminate the transceiver with a relatively high resistance with respect to the bus line are active.
In the second case of decentralized termination, the transceiver should terminate the bus with the characteristic impedance. To do so, the switches were closed by terminating resistors RT3, RT4. If the resistance values are RT3 = RT4 = ZL, the resulting resistance value is approximately equal to characteristic impedance ZL of the line (disregarding high-resistance voltage divider RTl, RT2).
In the third case, the switches of terminating resistors RT5, RT6, which preferably also correspond approximately to the characteristic impedance, were also closed. Therefore, half the characteristic impedance is approximately established as the terminating resistance.
The information about which resistance value is to be set may be reported to the transceiver via a switch, for example. Alternatively, the information may also be transmitted to transceiver 1 by the controller module. This information may

in turn be reported to the controller module via a switch or "a programmable interface.
Filter 3 usually contains inductances, so that it may be omitted in the integration for reasons of space and manufacturing. Under some circumstances, supporting network 4 need not be integrated into transceiver 1 but instead may be implemented externally by discrete resistances or by hybrid technology.
Figure 2 shows an alternative embodiment of a transceiver 1 without a filter, the switches on terminating resistors RT3-RT6 being replaced by fuses S3-S6. Fuses S5 and S6 are dimensioned such that they burn through at even lower current surges than fuses S3 and S4. Depending on the desired appliedcion, either ail four fuses are triggered (unterminated) or only fuses S5 and S6 are triggered (decentralized termination) or no fuses are triggered (centralized termination). The current surge may be triggered via transceiver core 2 or via the controller module, the particular height or duration in turn being adjusted by a switch.
As an alternative it is also conceivable for the terminating network to be designed as a separate circuit. In this case, the terminating network may be designed together with the supporting network and/or the filter as a separate module, for example, with the integration preferably being accomplished by hybrid technology.






What Is Claimed Is:
1. A transceiver for a control unit, comprising a
transceiver core by which a level adjustment of messages
received or to be sent is accomplished,
wherein an adjustable terminating network (5) is situated in the transceiver (1), at least two terminating resistance values being adjustable via this network, the terminating network (5) and the transceiver core (2) being monolithically integrated in a semiconductor circuit.
2. The transceiver as recited in Claim 1,
wherein at least three terminating resistance values are adjustable via the terminating network (5).
3. The transceiver as recited in one of the preceding
claims,
wherein the transceiver (1) includes two terminals (BUSHIGH/ BUSLOW) for connection to a two-wire bus system.
4. The transceiver as recited in Claim 3,
wherein bet ween the terminals (BUS HIGH/ BUSLOW) two first terminating resistors (RTl, RT2) are connected in series, two second terminating resistors (RT3, RT4) are connected in series, and two third terminating resistors (RT5, RT6) are connected in series, the center taps of the series being electrically connected and the second and third terminating resistors (RT3-RT6) being switchable on and/or off.
5. The transceiver as recited in Claim 4,
wherein switches or fuses (S3-S6) are associated with the terminating resistors {RT3-RT6).
6. The transceiver as recited in Claim 5,
wherein the switches are designed as transistors.

7. The transceiver as recited in one of the preceding
claims,
wherein a supporting network (4) is integrated in the transceiver (1).
8. The transceiver as recited in one of the preceding
claims,
wherein a filter (3) is integrated in the transceiver
(1) .


Documents:

3682-CHENP-2007 AMENDED CLAIMS 04-04-2013.pdf

3682-CHENP-2007 AMENDED CLAIMS 02-05-2014.pdf

3682-CHENP-2007 AMENDED PAGES OF SPECIFICATION 22-10-2013.pdf

3682-CHENP-2007 CORRESPONDENCE OTHERS. 10-12-2012.pdf

3682-CHENP-2007 EXAMINATION REPORT REPLY RECEIVED 22-10-2013.pdf

3682-CHENP-2007 FORM-1 22-10-2013.pdf

3682-CHENP-2007 FORM-3 04-04-2013.pdf

3682-CHENP-2007 OTHER PATENT DOCUMENT 04-04-2013.pdf

3682-CHENP-2007 OTHERS 02-05-2014.pdf

3682-CHENP-2007 POWER OF ATTORNEY 04-04-2013.pdf

3682-CHENP-2007 EXAMINATION REPORT REPLY RECEIVED 02-05-2014.pdf

3682-CHENP-2007 EXAMINATION REPORT REPLY RECEIVED 04-04-2013.pdf

3682-chenp-2007-abstract.pdf

3682-chenp-2007-claims.pdf

3682-chenp-2007-correspondnece-others.pdf

3682-chenp-2007-description(complete).pdf

3682-chenp-2007-drawings.pdf

3682-chenp-2007-form 1.pdf

3682-chenp-2007-form 26.pdf

3682-chenp-2007-form 3.pdf

3682-chenp-2007-form 5.pdf

3682-chenp-2007-pct.pdf


Patent Number 260576
Indian Patent Application Number 3682/CHENP/2007
PG Journal Number 20/2014
Publication Date 16-May-2014
Grant Date 09-May-2014
Date of Filing 23-Aug-2007
Name of Patentee VOLKSWAGEN AKTIENGESELLSCHAFT
Applicant Address 38436 Wolfsburg
Inventors:
# Inventor's Name Inventor's Address
1 LANGE, Klaus Peterskamp 18, 38108 Braunschweig
2 SCHANZE, Carsten Am Anger 54, 38448 Wolfsburg
PCT International Classification Number H04L 25/02
PCT International Application Number PCT/EP2005/013052
PCT International Filing date 2005-12-02
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10 2005 009 491.0 2005-02-24 Germany