DE102011080481B4 - System and method for automatic coding of a probe - Google Patents

Abstract

The system (1) according to the invention comprises an electronic measuring device (3) with at least one input (4) and a display element (5) and a probe head (2) for receiving a measuring signal (7). The probe head (2) is connected to a connection line (6) at an input (4) of the measuring device (3) and has a visual probe identification (8). The measuring signal (7) recorded by this probe (2) is displayed in a visual form on the measuring instrument (3), which corresponds to the visual probe identification (8). In this case, the probe (2) has a unique and predetermined probe identifier (8), which communicates the probe to the meter. The method describes the automatic coding of a probe (2) by the unique and predetermined probe identifier (8) from the probe (2) to the meter (3) is transmitted.

Description

The invention relates to a system and a method for the automatic coding of a probe, which is connected to an electronic measuring device, wherein the recorded measurement signal is displayed in a visual probe identification on the meter.

Electronic measuring devices, such as Oscilloscopes typically have several instrument inputs, to each of which a probe is connected to receive a measurement signal. Frequently, multiple probes are used to pick up different signals in a measuring arrangement and connected to the several available inputs of the meter.

To allow an assignment of the displayed signal to the receiving probe, describes the US 6,437,552 B1 an automatic probe identification system with a probe having a full spectrum LED light. Furthermore, the system comprises a measuring device whose inputs are provided with a channel identifier in the form of a color marking and a measurement signal which is supplied via an input, is displayed in the same color as the channel identifier fixed on the display. If a probe is connected to one of these inputs, the measuring device sends the channel ID to the probe, eg in the form of a 3-bit binary code. The LED lamp converts the code into a corresponding color and displays it. Thus, the probe, input on the meter and the external measurement signal are marked with the same color.

It is therefore the object of the present invention to provide a system of probe and measuring device, in which a signal which is recorded by a specific probe, the measuring device is always displayed in the probe associated with the identifier.

The object is achieved by the system according to the invention according to claim 1 and the inventive method according to claim 12. In the dependent claims advantageous developments of the system or method according to the invention are shown.

Often, however, it would be convenient and advantageous if the probe itself has a fixed color and the measured signal is displayed independently of the input on the meter to which the probe is connected in the corresponding probe color. A signal that is always tapped with a specific probe could thus always be displayed in the same color, without having to choose the assignment of the inputs to the meter accordingly, especially if several or all inputs are already occupied.

The inventive system comprises an electronic measuring device with at least one input and a display element and a probe for receiving a measurement signal. The probe is preferably connected to a connection line at an input of the measuring device and has a visual probe identification. The measurement signal received by this probe is displayed in a visual form on the meter that corresponds to the visual probe identification. In this case, the probe has a unique and predetermined probe identifier, which communicates the probe to the meter.

Thus, the visual expression of the measurement signal is permanently assigned to a probe, regardless of the device input to which the probe is connected. Thus, regardless of the occupancy of the meter inputs, a signal picked up by a particular probe, e.g. be displayed in its color, without having to change the probes on the meter. This also allows more measuring signals to be displayed as inputs on the measuring device. This is possible by changing the probe at an input, whereby already existing measured signals remain displayed.

It is also advantageous if the input of the meter to which the probe is connected displays the visual probe identifier. Thus, the input of the meter is clearly assigned to the displayed measurement signal. Frequently, parameters for representing the measurement signal, e.g. Offset or scaling, adjustable via setting elements that are first manually assigned to an input in order to change the measuring signal coming from this input. By displaying the visual probe identifier at the input of the meter, the association between the meter and the input is obvious.

It is also advantageous if the probe and the connecting line and / or the connecting line and the measuring device are connected to a connecting element, wherein the connecting element has a plurality of contact points and the probe identifier is coded by an assignment, in particular a short circuit or termination, the contact points. Such a short circuit (e.g., connection to ground) or termination (e.g., leaving open) of a contact point can be easily and quickly detected by the meter and read out by the meter.

It is also advantageous if the connection element has a contact point and the probe tag is set above a predetermined resistance, in particular between a ground contact and the additional contact point. This resistance coding is also simple, fast and inexpensive detectable. Key or resistor coding is applicable to both active and passive probes.

Advantageously, the probe has a memory unit containing the probe identifier in the form of a codeword, and a processor which is connected via a data line to the meter and transmits the codeword about it to the meter. This is a simple and flexible coding method especially for active probes that are already connected to a data line with the meter. In addition, such a codeword can be easily changed either by replacing the storage unit or by overwriting.

It is also advantageous if the probe identifier is determined via an identification element and the identification element is mounted exchangeably between the probe and the connecting line and / or between the connecting line and the measuring device. Thus, by a manual exchange of the identifier element, the probe identifier changed and thus the visual representation of the recorded measurement signal can be adjusted as needed.

Advantageously, the probe and the measuring device have at least one additional contact point for this purpose. The identification element itself provides at least one conductive connection between the at least one contact point on the side of the probe and the at least one contact point on the side of the measuring device or connection element. The probe identifier is coded by the assignment of the conductive connection between the at least one contact point on the side of the probe and the at least one contact point on the side of the measuring device. This makes it possible in a simple manner a variable encoding, especially for passive probes.

The advantages shown are effected in the same way by the inventive method for automatic coding of the probe.

Embodiments of the system according to the invention and the method according to the invention are illustrated by way of example in the drawing and are explained in more detail with reference to the following description. Show it:

1 an embodiment of a system according to the invention with a first embodiment of a probe according to the invention in a schematic representation;

2 a first embodiment of a connection element of the system according to the invention in a schematic representation;

3 a second embodiment of a connection element of the system according to the invention in a schematic representation;

4 A second embodiment of a probe according to the invention with connecting line and connecting element in a schematic representation;

5 a third embodiment of a probe according to the invention with identification element in a schematic representation and

6 An embodiment of the method according to the invention in flowchart representation.

Corresponding parts are provided in all figures with the same reference numerals.

1 shows an embodiment of a system according to the invention 1 with a probe 2 that has a connection line 6 to an entrance 4 of the meter 3 connected. The connection line 6 has at least one connection element 9 on, for example, is designed as a plug and thus connects the probe with the meter. Optionally, another connection element 9 ' be present at the other end of the connecting line and as a plug connection to the probe 2 serve. Thus, probes with integrated, non-detachable connection line as well as probes with a separate, changeable connection line are possible.

The probe 2 includes a unique and predetermined visual probe identifier 8th which is in a probe identifier display 12 clearly visible on the probe is attached. When inserting the connection element 9 in the entrance 4 the probe shares the probe identifier 8th the meter 3 With. The probe identification indicator 12 can be used as a ring or button in a specific color or with a printed line representation representing the visual probe identifier 8th represents, pronounced or configured. The probe identification indicator 12 may also be designed as an LED light that shines in a predetermined color that corresponds to the visual probe identifier.

The measuring device 3 includes a display element 5 for displaying the measuring signal recorded by the probe 7 , This is automatically displayed in the display, that of the visual probe identifier 8th on the probe 2 equivalent. The measuring device 3 has a coding table in which an association between the visual probe identifier 8th and whose coding is given. Advantageously, the inputs 4 of the meter 3 pronounced or designed in such a way that when inserting the connecting element 9 the entrance 4 in the visual probe identifier 8th lights. This can be done, for example, by a transparent zone around the perimeter of the entrance 4 be pronounced or designed, which is illuminated by a lamp in the meter, which lights up in the visual probe identifier, and thus a recognizable from the outside marking the input 4 generated. This visual probe identifier 8th at the entrance 4 simplifies the assignment of a measuring signal to the corresponding input. This is particularly advantageous if adjustment elements 10 eg for changing display parameters, such as the horizontal or vertical offset or the scaling of the measurement signal 7 are only once available and eg by controls 11 be assigned to an input.

The 2 and 3 show exemplary embodiments of the connection element 9 respectively. 9 ' containing a coding of the visual probe identifier 8th through one or more contact points 22 . 26 exhibit. To encode the visual probe identifier 8th has the connection element 9 next to a measuring line 21 , here eg a coaxial cable, several contact points 22 on, for example, as pins in a connector or as corresponding contact points 23 in a socket, are formed. The visual probe identifier 8th is by the assignment of these contact points 22 , eg by a short circuit (eg connection to ground) or an electrical termination (eg open without further connection).

In 2 For example, the first and the third contact point is characterized by a short circuit, for example with the ground line the coaxial cable. When connecting the connection element to the input 4 of the meter 3 becomes the occupation of the contact points 23 checked and via a coding table in the meter 3 determines the associated visual expression or design of the probe mark. That from the probe 2 supplied measurement signal 7 will then be in the visual probe identifier 8th , eg the displayed probe color, and the meter input 4 is lit in the same color. With the illustrated three contact points 22 Thus, eight different visual probe identifiers 8th be encoded.

In 3 is a second embodiment 30 of the connection element 9 shown that only one contact point 26 having. The contact point 26 is thereby connected to a certain resistance to a ground contact. In this case, a specific visual probe identification is assigned a specific resistance. This resistor coding requires only one contact point 26 and can thus save space eg in a connection element 9 . 9 ' to be ordered.

In 4 is an active probe as another embodiment 42 with connection line 46 and connecting element 40 respectively. 40' shown. In addition to the visual probe identifier 8th includes the probe 42 a memory element 43 and a microprocessor 44 , The storage element 43 , which is designed for example as EEPROM (Electro Erasable Programmable Read Only Memory), contains the visual probe identifier 8th in the form of a codeword via the microprocessor 44 and a data line 41 that in the connection line 46 is included, the codeword to the meter 3 Posted. As in the enlarged view of the connection element 40 is shown, the data line 41 , which is designed for example as a USB bus or LAN bus, in a corresponding socket on the meter 3 terminated. The data line 41 can be integrated together with the measuring line in a connecting line or designed as a separate data line and also as an integrated or separate connection element.

Is the storage element 43 formed as a writable memory element, for example as a flash EPROM, the code word and thus the visual probe identifier 8th , eg by connecting the probe via the data line 41 to a computer, to be changed. The probe identification indicator 45 can optionally be designed or formed as a variable or adjustable color LED, which lights up according to the stored codeword in a particular color.

5 shows a probe 52 with a connection element 50' . 50 between probe 52 and connection line 6 or between connecting line 6 and measuring device 3 , where between probe 52 and connecting element 50' and / or between connection element 50 and measuring device 3 an identification element 53 is introduced. The identification element 53 is, for example, annular and formed in a specific color. The identification element 53 can by pulling off the connection element 50 from the probe 52 or from the meter 3 be solved and exchanged.

The identification element 53 includes a body 57 , For example, made of a non-conductive material, a positioning mark 58 and at least one conductive connection 56 between contact points 54 of the probe 52 as well as contact points 55 of the connecting element 50' towards the meter. By a corresponding assignment of the contact points 55 For example, by short circuit (eg connection to ground) or a certain degree (eg open without further connection) according to the connection element in 2 , is the visual probe identifier 8th coded. Through the conductive connections 56 of the identifier element 53 becomes the occupation of the contact points 55 the meter changed so that the identifier element 53 the visual probe identifier 8th certainly. Thus, a probe 52 as needed with a visual probe identifier 8th be provided so that, for example, a signal that is always displayed in a particular color can still be displayed in the course of the assembled measuring arrangement with this color. When

Alternative may be the probe 52 and the connection element 50 . 50' only one contact point 54 . 55 and the identifier element 53 only a conductive connection 56 have, wherein the conductive connection 56 has a certain resistance and the visual probe identifier 8th as resistance coding accordingly 3 is transmitted.

An automatic coding by occupying multiple contact points or by resistance coding and the coding by means of an identification element is suitable for active and passive probes. Coding by a codeword according to the exemplary embodiment in FIG 4 is mainly suitable for active probes, as they have to be connected to a supply voltage anyway.

6 shows the individual process steps for the automatic coding of a probe summarized in a block diagram 60 , As a first step 61 Both measuring device and probe are provided. In the second process step 62 the probe is plugged into the meter input. The meter reads in the process step 63 the coding of the visual probe identifier on the connection element and compares in the process step 64 the coding with a coding table included in the meter 3 is included. The measuring device then displays the measuring signal in the transmitted visual probe identification on the display element. Optionally, the input of the measuring device in the visual probe identification is also displayed or illuminated.

All described and / or drawn features can be advantageously combined with each other within the scope of the invention. The invention is not limited to the described embodiments.

Claims (17)

A system for automatically coding a probe comprising: an electronic measuring device ( 3 ) with at least one input ( 4 ) and a display element ( 5 ), a probe ( 2 ) for receiving a measurement signal ( 7 ) located at an entrance ( 4 ) of the measuring device ( 3 ) and a visual probe identifier ( 8th ), wherein the measuring signal ( 7 ) in a visual expression on the display element ( 5 ) of the measuring device ( 3 ), which corresponds to the visual probe ID ( 8th ), characterized in that the probe head ( 2 ) a unique and predetermined visual probe identifier ( 8th ) and the probe ( 2 ) its visual probe identifier ( 8th ) to the measuring device ( 3 ) transmitted. System according to claim 1, characterized in that the visual probe identifier ( 8th ) is pronounced as a color representation. System according to claim 1 or 2, characterized in that the input ( 4 ) of the measuring device ( 3 ), where the probe ( 2 ), the visual probe identifier ( 8th ). System according to one of claims 1 to 3, characterized in that the probe head ( 2 ) a probe identification indicator ( 12 ) and the probe identification indicator ( 12 ) the predetermined visual probe identifier ( 8th ). System according to one of claims 1 to 4, characterized in that the probe head ( 2 ) via a connecting line ( 6 ) with the entrance ( 4 ) of the measuring device ( 3 ), that the probe ( 2 ) and the connecting line ( 6 ) and / or the connecting line ( 6 ) and the measuring device ( 3 ) with a connection element ( 9 ' . 9 ) are connected, wherein the connecting element ( 9 ' . 9 ) several contact points ( 22 ) and the probe identifier ( 8th ) by an assignment, in particular a short circuit or a conclusion, the contact points ( 9 ' . 9 ) is encoded. System according to one of claims 1 to 4, characterized in that the probe head ( 2 ) via a connecting line ( 6 ) with the entrance ( 4 ) of the measuring device ( 3 ), that the probe ( 2 ) and the connecting line ( 6 ) and / or the connecting line ( 6 ) and the measuring device ( 3 ) with a connection element ( 9 ' . 9 ) are connected, wherein the connecting element ( 9 ' . 9 ) a contact point ( 26 ) and the probe identifier ( 8th ) above a predetermined resistance value, in particular between a ground contact ( 24 ) and the contact point ( 26 ) is encoded. System according to one of claims 1 to 4, characterized in that the probe head ( 42 ) a storage unit ( 43 ) having the probe identifier ( 8th ) in the form of a codeword, and the probe ( 42 ) a processor ( 44 ), which via a data line ( 41 ) with the measuring device ( 3 ) and the codeword to the meter ( 3 ) transmits. System according to one of claims 1 to 4, characterized in that the probe head ( 2 ) via a connecting line ( 6 ) with the entrance ( 4 ) of the measuring device ( 3 ), that an identification element ( 53 ) the probe identifier ( 8th ) and the identification element ( 53 ) exchangeable between probe ( 52 ) and connecting line ( 6 ) and / or between interconnector ( 6 ) and measuring device ( 3 ) is introduced. System according to claim 8, characterized in that the probe head ( 2 ) and the measuring device ( 3 ) at least one contact point ( 54 . 55 ) and the identification element ( 53 ) at least one conductive connection ( 56 ) between the at least one contact point ( 54 ) on the side of the probe ( 52 ) and the at least one contact point ( 55 ) on the side of the meter ( 3 ) and the visual probe identifier ( 8th ) by the assignment of the conductive connection ( 56 ) between the at least one contact point ( 54 ) on the side of the probe ( 52 ) and the at least one contact point ( 55 ) on the side of the meter ( 3 ) is encoded. System according to claim 8 or 9, characterized in that the identification element ( 53 ) the visual probe identifier ( 8th ). System according to one of claims 1 to 10, characterized in that the measuring device ( 3 ) has an encoding table and by the encoding table an association between the coding of the visual probe identifier ( 8th ) and the visual expression in which the measurement signal ( 7 ) of the probe ( 2 . 42 . 52 ) is given. Method for the automatic coding of a probe ( 2 . 42 . 52 ) with the steps of: - providing ( 61 ) of an electronic measuring device ( 3 ) with at least one input ( 4 ) and a display element ( 5 ) and a probe ( 2 . 42 . 52 ) for receiving a measurement signal ( 7 ), wherein the probe ( 2 . 42 . 52 ) a visual probe identifier ( 8th ), - connecting ( 62 ) of the probe ( 2 . 42 . 52 ) to an entrance ( 4 ) of the measuring device ( 3 ), - Display ( 65 ) of the measuring signal ( 7 ) on the display element ( 5 ) in a visual expression corresponding to the visual probe identifier ( 8th ), characterized in that the probe ( 2 . 42 . 52 ) a unique and predetermined visual probe identifier ( 8th ) and the visual probe identifier ( 8th ) from the probe ( 2 . 42 . 52 ) to the measuring device ( 3 ) is transmitted. Method according to claim 12, characterized in that at the entrance ( 4 ) of the measuring device ( 3 ), where the probe ( 2 . 42 . 52 ), the visual probe identifier ( 8th ) is displayed. Method according to claim 12 or 13, characterized in that the visual probe identifier ( 8th ) by a different assignment of contact points ( 22 . 55 ) and / or by different resistance values ( 25 . 55 ) at a contact point ( 26 ) and / or coded by a codeword. Method according to one of claims 12 to 14, characterized in that the visual expression in which the measuring signal ( 7 ) of the probe ( 2 . 42 . 52 ) is represented by a coding table which indicates an association between the coding of the visual probe identifier ( 8th ) and the visual expression of the measuring signal ( 7 ) is determined. Method according to one of claims 14, characterized in that the codeword in a memory element ( 43 ) and can be changed. Method according to claim 12 or 13, characterized in that the probe head ( 2 ) via a connecting line ( 6 ) with the entrance ( 4 ) of the measuring device ( 3 ) that the visual probe identifier ( 8th ) by an identification element ( 53 ) and the identification element ( 53 ) exchangeable between probe ( 52 ) and connecting line ( 6 ) and / or between interconnector ( 6 ) and measuring device is introduced.

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