JPH0448269A - Digital oscilloscope - Google Patents

Abstract

PURPOSE:To make a waveform display information high density by constituting a display device so that multilevel can be displayed and enabling all informations to be displayed on the display screen of the limited quantity. CONSTITUTION:A display memory 4 is corresponded one to one to each display screen and constituted of plural memories 41-4n with the significance of luminance. By a waveform processor, when the quantity of waveform data is more as compared with the quantity of displayed picture elements, the waveform data are divided in a specified quantity for each to classify for groups, and the values of data and generating frequency of these data are obtained for every group and converted to display image data in the form such that the generating frequency is corresponded to the luminance, then stored in the display memory 4. The data in display memory 4 are combined together with the significance of luminance by a display device 5 and displayed with multilevel on the display screen. Thus, all informations of the data stored in the waveform memory 2 can be displayed on the display screen of the limited quantity (the quantity of picture elements of the display screen).

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Field of Application> The present invention relates to a digital oscilloscope, and specifically relates to increasing the density of waveform display information.

<Conventional technology> Digital oscilloscopes have been available for some time. This digital oscilloscope samples and digitally converts an analog input signal under the control of a sampling clock, stores the digital output in a waveform memory as a continuous series of waveform information, and then converts it into a tarokk under the control of a waveform processor. The contents of the waveform memory are synchronously read out, processed, and displayed as one waveform on a display screen with the horizontal axis as the time axis and the vertical axis as the waveform size.

<Problems to be Solved by the Invention> By the way, in such a conventional digital oscilloscope, when displaying data converted into digital data by an analog-to-digital converter (hereinafter referred to as an AD converter) on the screen, the number of data points is The score was limited to 500 to 2000 points. Therefore, if the length (capacity) of the waveform memory that stores waveform data is longer than that, for example, 1oo
When one continuous waveform data is stored in a memory with a capacity of kilowords, it is necessary to perform thinning processing to display a waveform with a length of 100 kilowords on the display, and the Nyquist frequency decreases due to thinning, and the waveform memory There was a problem in that the waveform data stored in the system was displayed as a waveform with some information missing.

On the other hand, analog oscilloscopes do not have this problem. This is because even on the same time axis as above, it is possible to display information waveforms of almost the entire band, including detailed information in changes in brightness.

The purpose of the present invention has been made in view of the above points, and it is possible to display all information on a display screen with a limited number of points when the number of data points of waveform data is larger than the number of displayed data points. Our goal is to provide digital oscilloscopes.

Means for Solving the Problems> In order to achieve such objects, the present invention converts an analog signal waveform into digital data using an AD converter, stores it in a waveform memory, and then displays the contents of the waveform memory on a screen using a waveform processor. In a digital oscilloscope that is converted into an image and displayed on the display screen of a display device, a memory that stores the data converted to a screen image, each of which corresponds one-to-one to the display screen and is weighted by brightness. If the number of data in the waveform memory is greater than the number of display pixels, the waveform processor divides the data into groups of n pieces of data, and divides each group into data values and waveforms. The display device is configured to have a function of determining the frequency of waveform occurrence and providing data in which the waveform frequency of occurrence corresponds to the luminance to the display memory, and the display device is configured to be capable of displaying gradations. .

Effects> In the present invention, the display memory is composed of a plurality of memories, each of which corresponds one-to-one to the display screen and is weighted in terms of brightness.

In addition, when the number of data points of the waveform data is larger than the number of display pixel points, the waveform processor divides the waveform data into groups by a predetermined number, and calculates the data value and the frequency of occurrence of that data for each group. is calculated, converted into display image data in a form in which the frequency of occurrence corresponds to the brightness, and stored in the display memory.

The display device combines the data in the display memory with luminance weighting and displays it on the display screen.

Thereby, all the information of the data stored in the waveform memory can be displayed on a display screen with a limited number of points (the number of pixels on the display screen).

<Example> The present invention will be described in detail below with reference to the drawings.

FIG. 1 is a configuration diagram showing an embodiment of a digital oscilloscope according to the present invention.

In the figure, l is an AD converter that converts an analog input signal into digital based on a predetermined sample clock, and 2 is an A/D converter that converts an analog input signal into a digital signal based on a predetermined sample clock.
A waveform memory stores output data of the D converter 1, and a waveform processor 3 is a microprocessor or the like.

4 is a display memory, which stores data from the waveform processor 3 in a data format that is easy to display with *g attached, and is made up of a plurality of memories each having an address that corresponds one-to-one to a pixel on the display screen. . Each display memory is weighted with gradation.

Reference numeral 5 denotes a display device capable of gradation display for displaying data in the display memory 4, and a CRT is usually used as the display device.

The operation in such a configuration will be explained next.

An analog signal is digitally converted by an AD converter 1 and stored in a waveform memory 2. A case where the number of waveform data points is 4@ which is the number of pixel points on the display screen will be explained. in this case,
The display gradation is also four gradations.

The data string in the waveform memory 2 is divided into four data groups as shown in FIG. 2, and each group (four data points) is displayed in one pixel column as shown in FIG. 3. The waveform processor 3 expresses the occurrence frequency information of the waveforms of each group by brightness. Of the four data, ■ data with four same values is the brightest, ■ data with three same values is the second brightness. ■ data with two same values is the third brightest brightness, ■ data with only one same value is the darkest brightness,
The data is converted so as to be stored in the display memory 4.

The display device 5 combines the weighting and luminance data from the plurality of memories in the display memory 4 and displays the data on the display screen. A display example is shown in FIG. 3(b). In the figure, the brightest gradation is represented by a black circle, the second lightest gradation is represented by a circle with a diagonal crosshair, and the third brightest gradation is represented by a circle with diagonal lines.

In addition to grouping in this way, by using a gradation display that incorporates waveform occurrence frequency information for each group, even if the waveform data exceeds the number of display pixel points, all waveform information can be included and displayed without being truncated. I can do it.

Note that the present invention is not limited to the embodiments, and various modifications can be made without departing from the purpose of the present invention.

For example, in the embodiment, the waveform data is divided into 4 pieces of data, and 41? Although the screen is displayed in Jjl, other division numbers and fil keys may be used.

In addition, if the relationship between the number of data in the waveform memory and the number of pixels on the horizontal axis of the display is different from the gradation value, it can be made to correspond in the same way by changing the number of data of the same value that changes the gradation. For example, 100 When displaying data divided into 16 gradations, the relationships shown in Table 1 are used.

Furthermore, the weighting of brightness can also be made variable. In that case, the weighting can be changed on the waveform processor 3 side or the display device 4 side. When performing this on the waveform processor 3 side, change the storage destination when storing data in the display memory 4, and when changing on the display device 4 side, combine the data by changing the weighting of the brightness when combining the data. .

Furthermore, it is possible to enlarge and display a specific portion on the time axis after capturing the waveform.

<Effects of the Invention> As explained in detail above, the present invention has the following effects.

(2) When the number of data in the waveform memory is larger than the number of pixels on the display time axis, displaying all the data and its waveform generation frequency at the same time increases the amount of information displayed, making it possible to identify side portions.

■In conventional digital oscilloscopes, aliasing occurs due to thinning, but in the case of the present invention, such aliasing does not occur.■When enlarging a specific part on the time axis after capturing a waveform, it is possible to display before and after enlarging. The waveform image does not change.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram showing an embodiment of a digital oscilloscope according to the present invention, FIG. 2 is a diagram for explaining grouping of waveform data, and FIG. 3 is an explanatory diagram for explaining the relationship between data content and display. It is. 1... AD converter, 2... Waveform memory, 3... Waveform processor, 4... Display memory, 5... Display device 3
F.

Claims (1)

[Claims] An analog signal waveform is digitally converted by an AD converter and then stored in a waveform memory, and then the contents of the waveform memory are converted into a screen image by a waveform processor and displayed on a display screen of a display device. In the digital oscilloscope, the waveform processor includes: a plurality of display memories that store data converted to a screen image, each of which corresponds one-to-one to a display screen and is weighted in terms of brightness; If the number of data in the waveform memory is greater than the number of pixels on the display, group it into groups of n data, calculate the data value and frequency of waveform occurrence for each group, and calculate the frequency of waveform occurrence corresponding to the brightness. The display device is configured to have a function of supplying the waveform data to the display memory, and the display device is configured to be capable of displaying gradation, so that all information regarding the data in the waveform memory can be simultaneously displayed on the display screen. A digital oscilloscope featuring: