Patent Description:
Although applicable in principle to any measuring system, the present invention and its underlying problem will be hereinafter described in combination with measuring a signal of a device under test.

<CIT> describes an apparatus and a method for the testing of circuit boards. Contact tips of a test finger of a finger tester are monitored during the testing process by an optical detection device. Their movement is corrected on the basis of the result determined by the optical detection device in such a way that the contact tip makes contact with the circuit board test point concerned.

<CIT> describes a measurement device with a measurement module and a measuring probe operably coupled to said measurement module. The measuring probe has at least one sensor at a distal end of said measuring probe. The sensor communicates sensor signals to said measurement module.

<CIT> describes a video universal meter which comprises a test signal input-output device, a control device, a measuring device, an imaging device, a video encoder, a video decoder and a display device. The imaging device is used for imaging the test signal input-output device and detecting electronic components of the test signal input-output device.

<CIT> describes an image capturing device assembly for use with a test probe and a testing system. The image capturing device assembly includs an image capturing device module configured for coupling to an external surface of the test probe and having an image capturing device housed within.

Due to the continuous miniaturization of electronic devices, the electronic circuits of the devices also become smaller and smaller. As a consequence, it becomes more and more difficult to get access to a measuring point for measuring a signal of the electronic circuit.

In particular, due to the miniaturization of the electronic circuits it is very difficult or almost impossible to precisely position a probe tip on a desired measurement point for measuring an electronic signal at the measuring point.

For monitoring the quality of devices or for repairing purposes it is necessary to measure the signals at specific measuring points. However, additional magnifying glasses or microscopes are cumbersome and require a complicated handling.

Against this background, a problem addressed by the present invention is to provide a probe tip, which can be precisely located at a desired measuring point. In particular, the present invention aims to provide an improved probe, which can assist a user when positioning the probe tip on a measuring point of an electronic circuit.

The present invention solves this problem with a probe tip and a method for applying a probe with the features of the independent claims. Further advantageous embodiments are subject-matter of the dependent claims.

According to a first aspect, a probe for measuring a signal at a measuring point is provided. The probe comprises a probe tip, an image capturing device and an image transmission interface. The probe tip is adapted to contact a measuring point for measuring a signal. The image capturing device is adapted to capture image data of an area around the probe tip. The image transmission interface is adapted to transmit the captured image data to a remote measuring apparatus.

According to a further aspect, a measuring system is provided. The measuring system comprises a probe according to the first aspect and a measuring apparatus. The measuring apparatus comprises an image receiving interface. The image receiving interface is adapted to receive image data transmitted by the image transmission interface of the probe.

According to still a further aspect a method for applying a probe at a measuring point is provided. The method comprises capturing image data of an area around a probe tip of a probe. The image data may be captured by an image capturing device arranged at the probe. The method further comprises transmitting the captured image data to a remote measuring apparatus. The transmission of the captured image data may be performed by an image transmission interface of the probe.

The present invention is based on the fact that precisely positioning a probe tip on a desired measuring point becomes more and more difficult with a reduced size of electronic circuits. At the one hand-side, the individual measuring points become smaller, and on the other hand-side, individual measuring points are very close together. Accordingly, a user needs additional support for precisely positioning a probe tip on a measuring point.

Thus, it is an idea of the present invention to assist a user when positioning a probe tip on a desired measuring point by additional image data of the environment of a probe tip. For this purpose, an image capturing device such as a camera is mounted on the probe carrying the probe tip. By combining the image capturing device and the probe tip on a probe, the image capturing device can always capture image data of an area of interest, i.e. the area surrounding the probe tip. Accordingly, the captured image data can be provided to a user and the user can monitor the positioning process without the need of any separate devices. In particular, the user does not need to move and control any other external devices such as magnifying glasses or the like.

Accordingly, the probe for measuring a signal according to the present invention comprises both, a probe tip and an image capturing device in combination. Thus, the image capturing device moves around in the same direction as the probe tip, and consequently, the image data captured by the image capturing device always provide image data of an area of interest.

The captured image data may be provided by an image transmission interface, which is also included in the probe. The image transmission interface may provide the image data captured by the image capturing device in any appropriate manner. For example, the images captured by the image capturing device may be provided by an analogue signal and in such a case, the analogue signal may be provided by an image transmission interface. However, it is also possible to provide the image data of the images captured by the image capturing device in digital form. For this purpose, any protocol may be possible.

The image transmission interface may forward the image data of the image capturing device to any appropriate device for displaying the image data. Some examples for providing the image data in an appropriate manner will be described in more detail below.

Further embodiments of the present invention are subject of the further sub-claims and of the following description referring to the drawings.

The image capturing device may comprise a dual camera or a stereo camera.

A mono camera may capture images from a single point of view, i.e. a fixed position with respect to the probe. A dual camera may comprise two separate optical systems for capturing image data. For example, each optical system may have different properties such as opening angle, depth of focus, color characteristics, etc. In particular, the individual camera elements of the dual camera may be directed even to different target points. A stereo camera may capture two almost similar images from different points of view. In this way, it may be possible to obtain three-dimensional information of the captured field of view. However, it is understood that any other appropriate camera system with camera elements may be possible. It may be possible to capture image data of a visible spectrum or even of invisible spectrum, for example infrared or ultraviolet light.

In a possible embodiment, the image capturing device is configured to capture wide-angle images and zoom images.

For example, separate camera elements may be used for simultaneously capturing wide-angle images and zoom images. Alternatively, the image capturing device may be configured to switch between a first mode for capturing wide-angle images and a second mode for capturing zoom images. Furthermore, the zooming and opening angle may be changed dynamically.

In a possible embodiment, the image capturing device is adapted to provide still images and/or an image sequence.

For example, the image capturing device may provide only an individual image upon request. Alternatively, it may be possible to provide a continuous stream of images captured with a predetermined frame rate. Accordingly, a user can easily recognize the movement of the probe tip on the electric circuit.

In a possible embodiment, the probe comprises a switch. The switch may be adapted to switch between an image capturing mode and a signal measuring mode.

By alternatively switching between an image capturing mode and a signal measuring mode, it may be even possible to provide the image data and a measuring signal via a same signal line or cable. Additionally or alternatively, it may be possible to use a same display for displaying the image data on a screen or alternatively displaying measurement results on the same screen. However, a switch may be also used for simply switching on or off the image capturing device.

In a possible embodiment, the probe comprises a lamp. The lamp may be adapted to illuminate at least the area around the probe tip.

The lamp may be, for example, a light-emitting diode (LED). However, any other appropriate light-emitting element may be also possible. By illuminating the area around the probe tip, images can be even captured in dark areas of an electronic circuit.

In a possible embodiment of the measuring system, the measuring system comprises a visualization device. The visualization device may be configured to display image data received by the image receiving interface.

The visualization device may be any appropriate device for displaying at a received image data. For example, the visualization device may be a display such as a screen. In particular, the visualization device may be a display of a measurement device, which can be also used for displaying measurement results. Some further examples of visualization devices will be described in more detail below.

In a possible embodiment, the visualization device comprises augmented reality glasses.

Augmented reality glasses may provide semitransparent images. Accordingly, the images provided by the semitransparent glasses can be recognized together with the real environment. For example, it may be possible to provide enhanced image data on the augmented reality glasses, which can assist a user when positioning the probe tip on a measuring point. For example, a zoomed image may be provided in the glasses, and a user can recognize the zoomed segment together with the real part of the electronic device.

In a possible embodiment, the visualization device is adapted to provide a three-dimensional representation of the image data received by the image receiving interface.

The three-dimensional representation may be provided by glasses for displaying three-dimensional content. Alternatively, it may be also possible to use any other appropriate technique for displaying three-dimensional content, for example a display screen dealing with polarized light or the like. Accordingly, by providing a three-dimensional representation of the area where the probe tip is moving, the user can be assisted by positioning the probe tip on a measuring point.

In a possible embodiment, the visualization device is adapted to selectively display either the image data received by the image receiving interface or measurement data of a signal measured at the measuring point.

In this way, a same display can be used for displaying the image data and for displaying the measurement results. Hence, the user may always look at a same display during the positioning procedure and during the successive measuring procedure.

In a possible embodiment, the measurement system comprises an optical stabilizing device. The optical stabilizing device may be adapted to compensate a shift in the captured image data, in particular a shift due to unwanted movements of the probe.

The compensation of the shift may be compensated by shifting pixels in the image data. Accordingly, the compensation of the shift is performed in an electronic way by data processing.

In a possible embodiment, the measuring system comprises a mechanical stabilization device. The mechanical stabilizing device may be adapted to mechanically equalize unwanted movements of the probe.

For example, the probe may be fixed to the mechanical stabilizing device such that the mechanical stabilizing device may control the movement of the probe, in particular the probe tip. For example, the mechanical stabilizing device may have a number of one, two, three or even more axis, which can be controlled. In particular, acceleration, tilt, or any other movement may be detected. For example, the mechanical stabilizing device may have an acceleration sensor or the like for detecting unwanted movements.

In a possible embodiment, the method for applying the probe may further comprise a step of receiving the transmitted image data. In particular the reception may be performed by an image receiving interface. The method may further comprise a step of displaying the image data received by the image receiving device. The image data may be displayed on a visualization device. The visualization device may be located at a spatial position remote to the measuring point.

With the present invention it is therefore now possible to assist a user when moving a probe tip in order to precisely position a probe tip at a small sized measuring point. By capturing image data of the probe tip by means of a camera which is mounted in a fixed position of the probe, it is possible to capture image data of an area surrounding the probe tip and providing the captured image data to a user. In particular, the image data may be provided in a magnified form such that a user can easily recognize the detailed position of the probe tip with respect to the desired measuring point. In this way, the positioning procedure of a probe tip on a measuring point can be simplified. The images due to an unwanted movement of the probe tip can be avoided and a probability of short circuits or the like during the measurement procedure can be reduced.

For a more complete understanding of the present invention and advantages thereof, reference is now made to the following description in conjunction with the accompanying drawings. The invention is explained in more detail below using exemplary embodiments, which are specified in the schematic figures of the drawings, in which:.

The appended drawings are intended to provide further understanding of the embodiments of the invention. They illustrate embodiments and, in conjunction with the description, help to explain principles and concepts of the invention. Other embodiments and many of the advantages mentioned become apparent in view of the drawings. The elements in the drawings are not necessarily shown in scale.

In the drawings, same, functionally equivalent and identical operating elements, features and components are provided with same reference signs in each case, unless stated otherwise.

<FIG> shows a schematic diagram of a probe <NUM> according to an embodiment. Probe <NUM> comprises at least a probe tip <NUM>, an image capturing device <NUM> and an image transmission interface <NUM>. Probe tip <NUM> may be an electric conductive tip for contacting a measurement point. For example, the measurement point may be a pin of an integrated circuit or another contact point of an electronic circuit. However, it is understood that probe tip <NUM> may be also able to contact any other appropriate measuring point of an electronic circuit. Probe <NUM> may further comprise a port or a cable for electrically connecting probe tip <NUM> with an input port of a measurement device.

Probe <NUM> further comprises the image capturing device <NUM>. In particular, image capturing device <NUM> may be firmly attached to a housing of probe <NUM>. The field of view of image capturing device <NUM> may be directed to probe tip <NUM>. Accordingly image capturing device <NUM> may capture images of an area surrounding probe tip <NUM>. Thus, when probe <NUM> with probe tip <NUM> is moving around on an electric circuit, image capturing device <NUM> may capture an image of probe tip <NUM> and the related area of the electric device. In this way, image capturing device <NUM> may capture images from potential measuring points, which may be contacted by probe tip <NUM>.

Image capturing device <NUM> may be a camera for capturing image data related to visible wavelength. In particular, image capturing device <NUM> may be a monochromatic or a colored camera for capturing image data. However, it may be also possible that image capturing device <NUM> may capture infrared or ultraviolet wavelength.

Image capturing device <NUM> may have a fixed, predetermined field of view related to a specific opening angle. However, it may be also possible that the field of view, in particular the opening angle of image capturing device <NUM> may be variable. Accordingly, the scale of zoom may be changed, for example may be changed depending on a desired application. For example, when dealing with very small sized devices, image capturing device <NUM> may capture a small field of view with a very high resolution. Furthermore, when dealing with devices of a larger scale, a larger field of view with a lower resolution may be captured by image capturing device <NUM>. The field of view and consequently the resolution may be adapted either manually or automatically.

Image capturing device <NUM> may continuously capture images, and provide the captured images as a continuous sequence with a predetermined frame rate. Alternatively, it may be also possible that image capturing device <NUM> may only capture a single image upon request. For example, image capturing device <NUM> may be triggered by an automated or manually provided trigger signal and provide a single image upon receiving the trigger signal. However, any other approach for providing images may be also possible.

Image capturing device <NUM> may provide the captured image data to image transmission interface <NUM>, and image transmission interface <NUM> may forward the image data to a corresponding remote device. Examples for such remote devices will be described in more detail below.

<FIG> shows a block diagram of a probe <NUM> according to a further embodiment. The embodiment according to <FIG> differs from the previously described embodiment in that the image capturing device <NUM> comprises two image capturing elements <NUM>-<NUM> and <NUM>-<NUM>. For example, the two image capturing elements <NUM>-<NUM> and <NUM>-<NUM> may be image capturing elements of a dual camera or a stereo camera. In case of a stereo camera, the two image capturing elements <NUM>-<NUM> and <NUM>-<NUM> capture images of a common area from different points of view. In this way, it is possible to obtain a three-dimensional view of the captured area.

The two image capture elements <NUM>-<NUM> and <NUM>-<NUM> have different opening angles.

Furthermore, it may be also possible that the two image capture elements <NUM>-<NUM> and <NUM>-<NUM> are directed to different areas.

For example, a first image capturing element <NUM>-<NUM> may capture wide-angle images, and a second image capturing element <NUM>-<NUM> may capture zoom images with a smaller opening angle. Furthermore, it may be even possible to use more than two image capturing elements <NUM>-<NUM> and <NUM>-<NUM>.

To illuminate the area covered by the one or more image capturing elements <NUM>-i, a lamp <NUM> may be arranged on the probe <NUM>. For example, the lamp may comprise one or more light-emitting diodes (LED) or any other kind of light-emitting element. In particular, the emitted light may be directed in the direction of the probe tip <NUM>.

Furthermore, probe <NUM> may comprise a switch (<NUM>) for switching between a first operation mode for capturing image data by the image capturing element <NUM> and a second mode for measuring signals by probe tip <NUM>. In particular, the image capturing element <NUM> may be switched off in the second operation mode. However, it may be also possible to maintain the operation of the image capturing element <NUM> when measuring the electric signals by probe tip <NUM>. In this way, it may be further possible to monitor the correct position of the probe tip at the measuring point during the measurement.

<FIG> shows a block diagram of a further embodiment with a probe <NUM>. Probe <NUM> in this embodiment mainly corresponds to the previously described probes <NUM> according to <FIG>. Further, probe <NUM> may be mounted on a mechanical stabilizing device <NUM>. The mechanical stabilizing device <NUM> may mechanical equalize an unwanted movement of the probe <NUM>. For this purpose, the mechanical stabilizing device <NUM> may comprise one or more controllable axis for moving or rotating probe <NUM>. In this way, the spatial position of probe <NUM> with the probe tip <NUM> may be spatially stabilized. For example, a gyroscope or an acceleration sensor or the like may be used for detecting a movement. Upon detecting an unwanted movement, the mechanical stabilizing device <NUM> may provide a controlled reaction for compensating such an unwanted movement.

Furthermore, the image data provided by image capturing device <NUM> may be analyzed in order to detect a movement of probe <NUM> and in response to such a detection of an unwanted movement, mechanical stabilizing device <NUM> may provide an appropriate response for compensating such an unwanted movement.

Additionally or alternatively, the image data provided by image capturing device <NUM> may be also compensated in order to obtain a stabilized image. For this purpose, pixels in the image data may be shifted to compensate unwanted movement in a resulting image. In this way, the image data may be processed in order to obtain stabilized image data.

<FIG> shows a block diagram of a measurement system according to an embodiment. The measurement system comprises a probe <NUM>, for example a probe <NUM> as described above in connection with <FIG>. Probe <NUM> may be connected to a measuring apparatus <NUM>. For example, probe <NUM> may be connected to measuring apparatus <NUM> by means of a cable. In particular, a single cable may be used for connecting probe <NUM> and measuring apparatus <NUM>. However, it may be also possible to use separate cables for connecting the probe tip <NUM> with measuring apparatus <NUM> and for connecting the image transmission interface <NUM> with a corresponding image receiving device <NUM> of the measuring apparatus <NUM>.

Image receiving device <NUM> of measuring apparatus <NUM> may receive the image data provided by image transmission interface <NUM>. The received image data may be processed and displayed on an appropriate display <NUM> of measuring apparatus <NUM>. For example, a same display <NUM> may be used for displaying measurement results and for displaying the image data provided by image capturing device <NUM>. For this purpose, it may be possible to switch between an image capturing mode for displaying the image data and a measuring mode for displaying the measurement results. Furthermore, it may be possible to provide the measurement results and the image data simultaneously. For example, a picture in picture configuration may be used, or the screen may be split for displaying the measurement results in a first part of the screen and displaying the image data in a second part of the screen. However, any other configuration of the screen may be also possible for providing image data and/or measurement results.

<FIG> shows a block diagram of a measurement apparatus according to a further embodiment. The measurement system according to <FIG> mainly corresponds to the previously described measurement signal according to <FIG>. The measurement signal according to <FIG> differs from the previously described measurement signal by a separate visualization device <NUM>. For example, visualization device <NUM> may comprise a visualization device for a three-dimensional visualization of image data, in particular of image data provided by a stereo camera of a probe <NUM>. For example, visualization device <NUM> may comprise glasses, in particular augmented reality glasses or virtual reality glasses for providing separate image content for each eye of a user. However, it may be also possible to provide the image content on any other kind of visualization device, in particular any kind of display such as a two-dimensional display or a display for providing three-dimensional image content.

<FIG> shows a block diagram of a method for applying a probe at a measurement point. In a step S1 image data are captured of an area around a probe tip <NUM> of a probe <NUM> by an image capturing device <NUM> arranged at the probe <NUM>. In a step S2 the captured image data are transmitted to a remote measuring apparatus <NUM> by an image transmission interface <NUM> of the probe <NUM>.

Furthermore, in a step S3 the transmitted image data may be received by an image receiving interface <NUM>, and in a step S4 the received image data may be displayed at a visualization device <NUM>, <NUM>, which is arranged to remote to a measuring point.

Claim 1:
Probe (<NUM>) for measuring a signal at a measuring point, the probe (<NUM>) comprising:
a probe tip (<NUM>), adapted to contact a measuring point for measuring a signal;
an image capturing device (<NUM>), adapted to capture image data of an area around the probe tip (<NUM>), and an image transmission interface (<NUM>), adapted to transmit the captured image data to a remote measuring apparatus (<NUM>), characterized in that
the image capturing device (<NUM>) comprises two capturing elements (<NUM>-<NUM>, <NUM>-<NUM>) and
wherein the two capturing elements have different opening angles.