Remote Display and Control for Test and Measurement Apparatus

Abstract

A remote display for a test and measurement apparatus is provided including a control panel. The control panel is removable and user-replaceable with an alternate control panel. The control panel can be connected to the remote display device to control and interact with the test and measurement apparatus, and to control the display of information on the remote display device.

Description

FIELD OF THE INVENTION

This invention is related generally to the collection of control buttons and knobs (configured to be manipulated as a cohesive control panel) used for controlling a test and measurement instrument, and more particularly to such a control panel including the matrix of control buttons and knobs which can be removed from the intended device to be controlled. Most particularly, the invention is related to an oscilloscope with such a removable control panel to permit 1) user interchangeable controls to be implemented that are determined to be best suited for the user's particular application; 2) the ability to control the target device remotely using standard computing equipment over a network with the aid of the product's standard removable control panel, including the standard control buttons and knobs to which the user has become accustomed and 3) the ability to control a secondary display and control device for use with the oscilloscope or other test and measurement apparatus.

BACKGROUND OF THE INVENTION

When controlling complex measurement equipment, it is well understood that the most commonly user-actuated commands and controls are assigned to pre-configured buttons and knobs configured into a matrix and typically placed within easy reach on the front of the instrument. Such a matrix is commonly referred to an instrument's control panel.

The debugging of electronic hardware requires a complex arrangement of test probes, cables and equipment connecting the device under test to the measurement equipment. These measurement instruments require a good deal of bench space for their footprint, and are constantly in competition with the object under test for scarce bench space. Unfortunately, the test and measurement device cannot be positioned too far from the device under test, because the user must frequently interact with the control knobs and buttons in order to adjust the most frequently used settings of the test and measurement apparatus.

Complex test and measurement devices, and oscilloscopes in particular, are by their very nature, multi-use instruments used for a variety of tasks. Manufacturers of these devices must therefore make careful tradeoffs about which functions to hard-code in the front panel controls. Some manufacturers offer different models of oscilloscopes which have controls designed for particular applications such as “disk drive analysis” or “serial data analysis”. These differing models have essentially the same hardware capabilities within the unit but simply differently configured front panel controls and software unique to the task at hand. The end user has no option to change or reconfigure the front panel controls if the immediate purpose of the unit changes over time.

In an attempt to address this issue, manufacturers have contemplated doing away with some of the hardware requirements, such as a control panel, in favor of a digitally displayed “soft” control panel shown to use on a portion of a display screen. Experience has shown that many if not most users of these devices prefer a hardware based display control with physical buttons and knobs.

The affection of end-users for physical knobs and buttons poses an additional dilemma for users that wish to control their instrument from a lengthy remote distance. Many test and measurement devices offer users the ability to control the device “remotely” through an electronic network such as Ethernet or GPIB. These devices permit transmission of commands and data to/from a generic local computing device such as a laptop or stationary computer. However the generic local computing device lacks the standard “short-cut” physical knobs and buttons that the user has become accustomed to using to control the instrument, thus decreasing the user's efficiency in using the device.

Many users of test and measurement equipment configure their instrument for use remotely in a semi-permanent installation. The ability to view and control that instrument from an office using a remote viewing and control panel would offer advantages to the user.

Therefore it would be beneficial to provide an improved apparatus that overcomes the drawbacks of the prior art.

Still other objects and advantages of the invention will in part be obvious and will in part be apparent from the specification and the drawings.

SUMMARY OF THE INVENTION

Therefore, in accordance with the invention, a test and measurement apparatus is provided including a fully removable, user-changeable control panel or remote viewing/control station.

The control panel may be attached to the test and measurement apparatus in a wired or wireless manner in order to retain the functionality of the panel, even when physically detached from the apparatus.

The control panel may be substituted by an alternate control panel with controls better suited for a particular application.

A remote viewing and control panel may be provided and allow a user remote access to the test and measurement apparatus.

The invention accordingly comprises the features of construction, combination of elements, and arrangement of parts which will be exemplified in the construction hereinafter set forth, and the scope of the invention will be indicated in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the invention, reference is made to the following description and accompanying drawings, in which:

FIG. 1 depicts a representation of an oscilloscope in accordance with the invention in which a removable control panel is in place in a traditional manner;

FIG. 2 depicts the oscilloscope of FIG. 1 with the removable control panel replaced by an alternate control panel better suited for a different application;

FIG. 3 depicts the removable front panel connected to a local generic computing device and being used to control the oscilloscope of FIG. 1;

FIG. 4 depicts a remote viewing and control station which is connected with a local generic computing device and being used to control and monitor the oscilloscope of FIG. 1; and

FIG. 5 depicts an oscilloscope provided with an additional display and control station and including a separate control panel associated with each display.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring first to FIG. 1, an oscilloscope 100 is shown. While the invention is described making reference to an oscilloscope, it should be understood that the invention is intended to apply to any type of test and measurement equipment, and to any apparatus including a display and an accompanying control panel. Oscilloscope 100 is preferably provided with a display 110, input/output ports 120 and a control panel 130. Control panel 130 includes knobs, indicators, buttons and the like as is well known in the industry. In FIG. 1, control panel 130 is depicted in a traditional location, thus providing a conventional oscilloscope layout. However, as will be discussed below, control panel 130 is in fact a removable control panel constructed in accordance with the invention, located in a conventional position.

In addition to the layout described, the control panel may be provided with a pointing device such as a track ball, joystick or other pointing mechanism. In such a manner a user may therefore manipulate a cursor or other pointing embodiment on the display from the control panel. Furthermore, a portion of the control panel may be reprogrammable to include one or more macro buttons, or other user definable portions thereof. Thus, a user may define a sequence of operations to be performed and associate that sequence with a particular control panel button or other indicator. This may allow a user to store such macros that are for complicated sequences for ease of use in the future. Preferable, these macros are stored in the control panel, or in the oscilloscope corresponding to an identifier of the control panel. So the customizable portion of the control panel may also be provided as a touch screen, with the displays thereon being programmable by the user.

Control panel 130 preferably remains operable when physically disconnected from oscilloscope 100. Thus, control panel may be adapted to communicate with oscilloscope 100 via a wired cable, a wireless link, or any other communication protocol that allows for signals to be transmitted to and from the control panel for use in controlling the operation of oscilloscope 100, and/or the display of information of display 110/111. Such wireless connection may comprise wireless USB, Bluetooth, wireless LAN, ultra wideband, or any other appropriate wireless communication protocol.

Referring to FIG. 2, control panel 130 may be replaced with an alternate control panel 140 to enable alternate, efficiency-improving shortcut keys and access to task-specific controls. Thus, it is contemplated that one or more alternate control panels may be provided, and use, based at least in part upon the type of measurements to be made by a user. Such an alternate control panel may be the same or a different size that the original control panel. If larger, the alternative control panel may be configured to overhang from the edge of the oscilloscope, or alternatively overhang the display. In such a case, the useable portion of the display may be reduced. Such replaceable functionality also eases the ability to repair the oscilloscope, and any problems with a knob or other portion of the control panel may be remedied simply be replacing the panel.

In addition to providing such an alternative control panel, a so called blanking panel may be provided that may replace the control panel. Such a blanking panel may fit into the control panel location but include no buttons, knobs, or other features, or at least includes a limited number of these features. The blanking panel may be inserted after a user has set up an oscilloscope, and wants to insure that no other person changes any of the settings. Alternatively, the blanking panel may include a designation to lock the oscilloscope as noted above, or allow only for remote control of the oscilloscope.

Each removable control panel or blanking panel may also key the oscilloscope to access a particular option or change the operation mode of the oscilloscope. For example, insertion of a particular control panel, such as a spectrum analyzer panel, may cause the oscilloscope to change modes to operate as a spectrum analyzer. Preferably, the design of the control panel will include function buttons and indicators related to this alternate operation mode. Similarly, insertion of the control panel may cause the oscilloscope to load a particular software option or the like.

In a situation where a user of an oscilloscope may store sensitive information, or make measurements that produce sensitive information, it is contemplated that the control panel or blanking panel includes a flash or other memory storage. Such sensitive information may be stored on this memory, and therefore, a user is able to remove the control or blanking panel along with the sensitive information to a secure location when not in use. In addition to allowing for security, it allows another user to replace another control panel into the oscilloscope and use the oscilloscope without risk of receiving or seeing the sensitive information.

In addition to being removably attached to oscilloscope 100, alternate control panel 140 and control panel may communicate with each other, whether directly or via oscilloscope 100, to exchange information therebetween. Such information may include setup information, user information or the like. In this manner, any information stored in control panel 130 can be easily transferred to alternate control panel 140.

Referring to FIG. 3, control panel 130 may also be connected to a local computing device 150 and the combination may be used to interact remotely with device 100 via connection 170. Thus, such a control panel may be attached to the local computing device via a USB, Bluetooth, or other appropriate wired or wireless connection scheme. Thus, control panel may be adapted to communicate with local computing device 150 via connection 160 which may be a wired cable, a wireless link, or any other communication protocol that allows for signals to be transmitted to and from the control panel for use in controlling the operation of oscilloscope 100 via local computing device 150, and/or the display of information of display 110. Such wireless connection may comprise wireless USB, Bluetooth, wireless LAN, ultra wideband, or any other appropriate wireless communication protocol.

Upon connection thereto, preferable, software contained within local computing device 150 already adapted to control device 100 remotely recognized the control panel 130, or alternate control panel 140. Upon recognition, the local computing device is able to receive commands from the control panel and implement them in controlling the device 100 as if the control panel were still connected to device 100.

Referring next to FIG. 4, an oscilloscope may be provided with one or more additional display 190. Each such additional display may be coupled with a control panel 130 in a manner described above for coupling the control panel to the test and measurement apparatus. The combination of such display and control panel will be collectively referred to as display/control device 180. Display/control device 180 may be connected to local computing device 150. This combination may in turn be used to interact remotely with device 100 via connection 170. Thus, such a control panel may be attached to the local computing device via a USB, Bluetooth, or other appropriate wired or wireless connection scheme. Thus, display/control device may be adapted to communicate with local computing device 150 via connection 160 which may be a wired cable, a wireless link, or any other communication protocol that allows for signals to be transmitted to and from the control panel for use in controlling the operation of oscilloscope 100 via local computing device 150, and/or the display of information of display 110. Such wireless connection may comprise wireless USB, Bluetooth, wireless LAN, ultra wideband, or any other appropriate wireless communication protocol.

Alternatively, display/control device 180 may also include communication equipment sufficient to maintain a direct connection to device 100 in any of the manners described above for communication between local computing device 150 and device 100. In this manner, display/control device 180 may comprise a stand alone workstation for use with a remotely operating device 100. Additionally, display control device 180 incorporates all of the possible features and alternative embodiments related to control panel 130 noted above with respect to device 100.

Referring next to FIG. 5, an oscilloscope may be provided that includes one or more additional display 290 and control 210 stations, collectively referred to as device 280. In this particular embodiment, device 100 may communicate directly with device 280 via connection 220, which may comprise a wired cable, a wireless link, or any other communication protocol that allows for signals to be transmitted to and from the control panel for use in controlling the operation of oscilloscope 100, and/or the display of information of display 110. Such wireless connection may comprise wireless USB, Bluetooth, wireless LAN, ultra wideband, or any other appropriate wireless communication protocol.

In accordance with the invention, a separate control panel may be associated with each display. This association may comprise a physical or data transfer connection, and may include all of the features noted above with respect to control panel 130 and its relationship with device 100. In such a case, it is contemplated that each control panel may control the display of information, and the underlying processing of data corresponding to its associated display. Furthermore, each control panel may provide each of the features noted above, such a keying the display into a particular mode of operation, storing sensitive information and the like. Thus, control panels with different designs may be associated with device 100 and 280 at the same time, thus allowing for multiple users to operate device 100 in multiple modes, nearly simultaneously, subject to the ability of device 100 to operate in more than one mode. Multiple devices 280 may be coupled to a single device 100 as desired, once again subject to the ability of device 100 to run in multiple modes simultaneously, or in an interleaved manner.

While the invention has been described applicable to an oscilloscope, the invention is intended to be equally applicable to other test and measurement apparatuses and to electronic apparatuses in general.

It will thus be seen that the objects set forth above, among those made apparent from the preceding description, are efficiently attained and, since certain changes may be made in the above construction(s) without departing from the spirit and scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawing(s) shall be interpreted as illustrative and not in a limiting sense.

It is also to be understood that the following claims are intended to cover all of the generic and specific features of the invention herein described and all statements of the scope of the invention which, as a matter of language, might be said to fall there between.

Claims

1. A test and measurement apparatus, comprising: a remote display device adapted to be maintained in communication with the test and measurement apparatus, the remote display device comprising a control panel, wherein the control panel is selectably removable.

2. The test and measurement apparatus of claim 1, wherein upon attachment of the control panel to the remote display device, an electrical contact is made.

3. The test and measurement apparatus of claim 1, wherein the control panel is maintained in communicating contact with the remote display device when removed via a wired connection.

4. The test and measurement apparatus of claim 1, wherein the control panel is maintained in communication contact with the remote display device when removed via a wireless connection.

5. The test and measurement apparatus of claim 1, wherein the removed control panel is operable to control the remote display device.

6. The test and measurement apparatus of claim 1, where the remote display device is maintained in communicating contact with the test and measurement apparatus via connection to a local computing device remotely controlling the test and measurement apparatus.

7. The test and measurement apparatus of claim 6, wherein the remote display device is maintained in communicating contact with the remote computing device via a wired connection.

8. The test and measurement apparatus of claim 6, wherein the remote display device is maintained in communication contact with the remote computing device via a wireless connection.

9. The test and measurement apparatus of claim 6, wherein the remote display device controls the test and measurement apparatus via a local area network.

10. The test and measurement apparatus of claim 6, wherein the remote display device controls the test and measurement apparatus via a wireless network.

11. The test and measurement apparatus of claim 1, wherein the remote display device further comprises a second control panel, the second control panel adapted to be removably attached to the remote display device in place of the control panel.

12. The test and measurement apparatus of claim 11, wherein the second control panel has a configuration different from the control panel, and is adapted for use by a user for a purpose different from that of the control panel.

13. The test and measurement apparatus of claim 1, wherein the control panel is adapted to control the test and measurement apparatus to perform a desired processing and display the results of such processing on the remote display device.

14. The test and measurement apparatus of claim 13, the desired processing requested by the control panel is different from a processing being performed by the test and measurement apparatus, the results of which being displayed on a display associated with the test and measurement apparatus.

15. The test and measurement apparatus of claim 1, wherein the test and measurement apparatus is an oscilloscope.

16. The test and measurement apparatus of claim 1, further comprising a pointing device on the removable control panel for manipulation of a pointing cursor on the remote display device.

17. The test and measurement apparatus of claim 1 further comprising one or more programmable buttons on the removable control panel, each of the programmable buttons being programmable to perform one or more processes on the remote display device.

18. The test and measurement apparatus of claim 1, further comprising a programmable touch screen on the removable control panel.

19. The test and measurement apparatus of claim 1, further comprising a blanking panel, the blanking panel adapted to be removably attached to the remote display device in place of the control panel.

20. The test and measurement apparatus of claim 19, wherein upon installation of the blanking panel, adjustment of the remote display device is disabled.

21. The test and measurement apparatus of claim 1, wherein attachment of the removable control panel to the remote display device launches installation of a software option on the test and measurement apparatus associated with the removable control panel, for use with the remote display device.

22. The test and measurement apparatus of claim 1, wherein attachment of the removable control panel places the test and measurement apparatus in an operation mode associated with the removable control panel, for use with the remote display device.