DE10018356B4 - Method for identifying an electronic control unit and suitable control unit - Google Patents

Abstract

A method of identifying an electronic controller in a test procedure, comprising the steps of:
- Is applied to the control unit to be identified in the manufacture of a network of resistive positions coded label formed as a parallel arrangement of resistance positions with two terminals, whose position and / or resistance characterize a variant of the controller, and provided with test points is
- electrical circuits and components of the control unit are tested in a circuit tester,
- electrically conductive test needles are placed in pairs on the test points during the test procedure and each circuit is closed,
- Voltage drops between the test point pairs are measured, and
- It is determined by an evaluation of the measured voltage drops, the variant of the tested electronic device.

Description

The The invention relates to a method for identifying an electronic ECU and one for that suitable control unit, for example a control unit for one Airbag in a motor vehicle.

at The mass production of airbag control units often become different Variants of the same device manufactured. The variants differ externally in their application and their functionality. So there are variants with a different one Number of ignition circuits. From the manufacturing point of view, these variants differ, all as a printed circuit on a same board or printed circuit board can be applied by their quantity of equipment or by the equipment with different components.

In In practice so far the different variants are over theirs Plug identified, the "mechanical are coded differently ", this means where each variant mechanically differently formed Plug has. This possibility for identification fails however with a Fehlbestückung of the ECU or even if, demanded by a customer, two variants the have the same plug coding.

Known it is also, actuators with different electrical data, for example, fuel injectors, thereby identifying that they are coded in the form of a resistance whose resistance value is determined by a control unit the voltage drop across the resistor is detected (US-A 4,972 293). A first digit of the numerical value of the voltage drop represents the coded amplification of the Actuator, while the second digit of the voltage drop of its encoded offset represents. To distinguish different variants of electronic ECUs this method is not suitable.

In a known disk, for. As a bank card, credit card, access card or the like, the disk is provided with an integrated circuit having, inter alia, a memory unit in which a characteristic value is written, from which the authorization of the cardholder results ( DE 42 43 888 A1 ). Since such characteristics can be copied to produce counterfeits, a method of simplifying authentication of such volumes using a physical characteristic of the integrated circuit is described.

With an authorization card in the form of a chip card, access to a venue or room or public transport is granted, preferably for a limited number of days, for example for one week ( FR 2 745 932 A1 ). The card should be able to be read in a card reader, in which also normal, longer valid and more elaborately manufactured chip cards are read. It therefore has the same standardized dimensions as the common chip cards.

Of the Invention is based on the object, the variants of an electrical or electronic device while the production with a coded marking, the allows, the respective variant in a subsequent test procedure clearly identifiable.

The The object of the invention is achieved by a method according to claim 1 and by a controller after Claim 5 solved. Appropriate further education The invention are laid down in the subclaims.

The Advantages of the invention include the fact that they are easier Way a unique identification of variants of an electric equipment enable. There are also assembly errors recognized the label. Identifying is very economical, there is hardly any additional requires equipment and time. The detection of Variant of the device takes place during an already made electrical circuit test (a In-circuit tests), in which the components with which a PCB equipped is to be measured electrically.

The Method is suitable for other electrical and electronic Circuits and / or components containing devices, such as measuring and monitoring devices that to be electrically tested for their function after manufacture Framework of this exam to identify.

embodiments The invention will be explained below with reference to the drawing. It demonstrate:

1 a test device with which an identification is carried out according to the method according to the invention;

2 an electronic control device provided with a coded identifier;

3 a table with a Codierungsbei play, and

4 an executed in carrying out the method according to the invention program in the form of a flow chart.

A tester 1 for checking control devices, for example motor vehicle airbags, has circuit components 2 - the so-called hardware - such as sensors, actuators, voltage and current sources, current and voltage meters, etc. Such test equipment 1 are referred to as so-called in-circuit testers (in the following also: ICT). The expiration of the tester 1 The test procedure is carried out by a computer 3 with associated programs - the so-called software - controlled. The computer 3 is through a control line 4 with the tester 1 connected.

The tester 1 also has an ICT test head 7 on that with test needles or probes 8th is provided and with the hardware 2 via a multiple signal line 6 or a data bus is connected. To a control unit 9 The ICT test head is to be tested on the control unit 9 introduced until the electrically conductive test needles rest on appropriate test points on the control unit. Thereafter, the test needles test circuits are closed with which the function of the circuits of the control unit 9 is checked. In that regard, ICT test equipment are known in the art.

The control unit 9 is usually designed as a printed circuit board and equipped with electrical and electronic components whose nature and number of the respective control unit variant depends. Details of the controller are not shown here, since such circuit boards are well known. On the printed circuit and the test points are provided with which the test needles 8th contact. The direction of movement of the test head is indicated by an arrow 10 indicated.

The control unit 9 consists essentially of a printed circuit board 12 ( 2 ) with the already mentioned printed circuit with tracks 11 and the - not shown here - soldered or glued components. It is also with a coded label 14 provided, which designates the variant or the type of the control unit and which allows a simple automated identification of each variant present. The marking consists of a resistance network or network of resistance positions R1, R2, R3, R4 and R5, which are connected with their one terminal or pole to a first test point i and with their respective second terminals to associated second test points j ₁ to j _n . In the present example, n = 5.

The resistance positions R1, R2, R3, R4 and R5, as shown in the drawing, can be arranged electrically parallel. Expediently, they can furthermore be connected with their one connection to a first common test point i and with their respective second connection to separate second test points j ₁ to j _n . This simplifies the manufacture and testing of the marking. In addition to the Darge presented parallel arrangement of the resistance positions R1-R5 can also be provided a matrix arrangement of the network.

The marking 14 is encoded via the resistance values of the resistors which are used to load the individual resistance positions, for example with a binary character. Such coding is independent of the components with which the circuit board 12 is equipped. It can be supplemented with an additional "parity resistance position", so that a mistake when fitting the circuit board 12 detected with coding resistors and can be corrected if necessary.

In an in-circuit test, the components on the circuit board 12 measured electrically. For this it is necessary to use the circuit board or circuit board 12 provided with defined test points, via which the components to be tested are integrated into a test circuit. The test circuit is closed as soon as the electrically conductive test needles 8th are placed on the test points.

To do this, the tested variant of the control unit 9 recognize the test needles 8th on the one hand on the first test point i and on the other hand on the second test points j ₁ to j _n set up and closed a circuit. In this case, the value of the "coding resistance" is detected at each position R1 to R5 and thus the identification is identified, ie the control unit variant identified Alternatively, the value of the "coding resistance" at each position R1 to R4 and the value of the "parity resistance" at the In the case of binary coding, the resistors may be of any value 1 Electrically only determines whether a resistor is present at a resistance position or not.

• Variante 1: 00011 = Pos. 1 bis 3 nicht bestückt, Pos. 4 bestückt, Parität bestückt
• Variante 2: 00101 = Pos 1 bis 2 nicht bestückt, Pos 3 bestückt, Pos 4 nicht bestückt, Paritätsposition bestückt
• Variante 3 00110 = Pos 1 bis 2 nicht bestückt, Pos 3 und 4 bestückt, Paritätsposition nicht bestückt,

usw.The following table shows an example of a binary coded even parity tag:

• Variant 1: 00011 = Pos. 1 to 3 not equipped, pos. 4 populated, parity fitted
• Variant 2: 00101 = Pos 1 to 2 not equipped, Pos 3 equipped, Pos 4 not equipped, parity position populated
• Variant 3 00110 = Pos 1 to 2 not equipped, Pos 3 and 4 populated, parity position not equipped,

etc.

With five resistors, binary coding is known to form 2 ⁵ = 32 different identifiers. If only four resistors are used, which is likely to be sufficient in most cases, the fifth resistor allows error detection by fitting the fifth resistor position to give even or odd parity. This indicates whether a resistance has been applied too little or too much.

A second embodiment of the coding is shown in the table of FIG 3 shown. Here, each variant is characterized by a resistor network, in which the values of the individual resistors have been selected in a variant-specific manner. The sum of the populated resistance values is always the same. The circuit board tester 1 detects by measuring the voltage drop in the test circuit - specific for each variant - what value each resistor has.

Is a resistor when loading the PCB 12 has been forgotten, can still be made on the other resistor identification of the control unit variant. In this example, two errors can be detected and one error corrected. In such coding, the resistance values should be chosen to be in the circuit of the controller 9 occur in any or no variant.

S1

Zu Beginn wird ein Feldzähler n auf den Wert null gesetzt.

S2

Eine an dem Testpunkt i anliegende Testnadel 8 wird mit einer an dem Testpunkt j anliegenden Testnadel über eine Stromquelle verbunden.

S3

Es wird der Spannungsabfall U_mess = U_j – U_i zwischen den Testnadeln gemessen.

S4

Es wird abgefragt ob U_mess < GW₁ (erster Grenzwert) ist?

S5

Falls ja, wird eine Feldvariable der Parallelanordnung oder Matrix) an = 0 gesetzt, wobei n ein Feldzähler ist.

S6

Falls nein, wird a_n = 1 gesetzt.

S7

Der Feldzähler wird um eins erhöht: n = n+1.

S8

Es wird abgefragt ob n ≥ GW₂ (zweiter Grenzwert) ist? Falls nein, erfolgt ein Rücksprung zu Schritt S2. Falls ja:

S9

Erfolgt eine Auswertung der gemessenen Werte für n = 0 bis n = GW₂.

S10

Es wird abgefragt, ob eine Steuergerätevariante erkannt worden ist? Falls ja, ist das Programm am

S11

Ende angelangt. Falls nein, wird in

S12

die Kennzeichnung als fehlerhaft erkannt.

To the variant of the respectively tested control unit 9 to identify according to the inventive method, the calculator works 3 of the circuit board tester 1 a program whose flow chart is off 4 is apparent and has the following program steps S _n :

S1

At the beginning, a field counter n is set to the value zero.

S2

A test needle applied to the test point i 8th is connected to a test pin applied to the test point j via a power source.

S3

The voltage drop U _mess = U _j -U _i between the test needles is measured.

S4

It is queried whether U _mess <GW ₁ (first limit) is?

S5

If so, a field variable of the parallel array or matrix is set to = 0, where n is a field counter.

S6

If no, a _n = 1 is set.

S7

The field counter is incremented by one: n = n + 1.

S8

It is queried whether n ≥ GW ₂ (second limit value) is? If not, a return to step S2. If so:

S9

An evaluation of the measured values takes place for n = 0 to n = GW ₂ .

S10

It is queried whether a control unit variant has been detected? If yes, the program is on

S11

Arrived at the end. If no, will be in

S12

the identification recognized as defective.

The Program will be at the exam the next ECU again processed.

In summary, the method according to the invention will now be described as follows. On a surface of the controller 9 In the manufacturing process, a coded label consisting of a network of resistance positions R1-R5 is produced 14 applied, provided with test points i, j _n and equipped with resistors whose position and / or value characterize a variant. In an in-circuit test, electrically conductive test needles 8th put in pairs on the test points and closed a circuit over them. Evaluation of voltage drops between the test point pairs gives the device variant.

Claims (9)

Method for identifying an electronic ECU during a test procedure, which includes the following steps: - on the to be identified control unit becomes one of a network of resistive positions in the making existing coded marking applied as a parallel arrangement formed of resistance positions, each with two terminals is whose position and / or resistance characterize a variant of the control unit, and which is provided with test points, - electrical circuits and Components of the control unit are tested in a circuit tester, - electric conductive test needles are used during the test procedure put it in pairs on the test points and it gets over them one circuit each closed, - there will be voltage drops between measured the test point pairs, and - it will be evaluated the measured voltage drops the variant of the tested electronic device detected. A method according to claim 1, characterized in that the resistance positions with their one connection to a common first test point and with their respective second connection to corresponding second test points are connected. Method according to one of claims 1 to 2, characterized that the resistance positions are binary coded resistance values be assigned. Method according to one of claims 1 to 3, characterized that the resistance positions individually specified resistance values be assigned whose sum results in each case the same value. Control device suitable for carrying out the method according to one of the preceding claims, characterized in that it is provided with a marking ( 14 ) consisting of a network of resistive positions (R1-R5). Control device according to claim 5, characterized in that the marking ( 14 ) consists of a parallel arrangement of resistance positions (R1-R5) with two terminals each, which are connected on the one hand to a first test point (i) and on the other hand to a respective second test points (j ₁ - j _n ). Control device according to claim 5 or 6, characterized in that the marking ( 14 ) consists of a matrix arrangement of resistance positions (R1-R5), which are each connected to a terminal to a first test point (i) and with their respective second terminal to associated second test points (j ₁ - j _n ). control unit according to one of the claims 5 to 7, characterized in that the resistance positions (R1-R5) resistors whose values represent a binary coding. control unit according to one of the claims 5 to 8, characterized in that the resistance positions (R1-R5) resistance values are assigned, which are set individually and whose sum gives the same value.