JP2007292574A - Indicating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indicating device capable of carrying out scale changes, without the user receiving unexpected impressions or feeling of discomfort. <P>SOLUTION: A CPU switches a normal scale image 12 to a magnified scale image 15, such that the indication position of a pointer image 13 on the normal scale image 12 which is displayed on a liquid crystal display, coincides with the indication position of the pointer image 13 on the magnified scale image 15. Furthermore, the CPU displays the magnified scale image 15 on the liquid crystal display, while gradually making the density of the normal scale image 12 small, until the normal scale image 12 disappears from the liquid crystal display, and gradually makes the density of the magnified scale image 15 large, until the density becomes a prescribed value, and the scale images are switched. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an indicating device, and more particularly to an indicating device that displays an indicating instrument image in which a pointer image is superimposed on a scale image.

  Conventionally, for example, as shown in FIG. 9, it is known to display an indicating instrument with an image using a display such as a CRT or LCD. As shown in the figure, this indicating instrument is composed of, for example, a TFT-liquid crystal display. On the liquid crystal display, for example, a scale image 10 indicating the rotation speed (measurement target value) of the vehicle engine and a pointer image 13 (pointer) superimposed on the scale image 10 are displayed.

According to the indicating instrument described above, since the scale indicating the engine speed is displayed as an image, the scale of the scale image 10 can be switched as shown in FIGS. 9 (A) and 9 (B). As shown in FIG. 2A, a scale image 10 of 0 (rpm) to 10 × 1000 (rpm) is normally displayed on the liquid crystal display. On the other hand, for example, when the user presses a scale change button (not shown), the scale image 10 of 2 × 1000 (rpm) to 8 × 1000 (rpm) is displayed on the liquid crystal display in the same range. Thereby, the scale change which was not realizable in the conventional indicator meter which has arranged the pointer on the scale plate becomes possible.
JP 2000-330093 A JP 2004-237844 A JP 2005-239042 A JP 2004-322803 A

  However, the simple switching from the display shown in FIG. 9A to the display shown in FIG. 9B is a sudden change for the user, and there is a problem that a sense of discomfort is great. Moreover, since the position of the pointer image 13 changes suddenly according to the scale image 10, there is a problem that it is not preferable for visual recognition.

  Therefore, the present invention focuses on the above-described problems, and an object of the present invention is to provide an instruction device that allows a scale change without a sense of incongruity without receiving a sudden impression.

  In order to solve the above-mentioned problems, the invention according to claim 1 is characterized in that a display means for displaying a scale image indicated by a pointer, an input means for inputting a measurement object value detected by a sensor, and the scale image A pointer moving means for moving the pointer so as to indicate the measurement target value, and one of the scale images displayed on the display means among the at least two scale images having different scales in accordance with the switching command. In the pointing device including switching means for switching to the scale image, the switching means is configured so that the indicated position of the pointer on the one scale image matches the indicated position of the pointer on the other scale image. The pointing device is characterized by switching from the one scale image to the other scale image.

  According to the first aspect of the present invention, the switching means switches from one scale image to the other scale image so that the indicated position of the pointer on one scale image matches the indicated position of the pointer on the other scale image. Therefore, even if switching from one scale image to the other scale image, the indicated position of the pointer does not change.

  The invention according to claim 2 is characterized in that the switching means reduces the density of the one scale image stepwise until the one scale image disappears from the display means in response to the input of the switching command. 2. The indication according to claim 1, wherein the other scale image is displayed on the means, and the scale image is switched by gradually increasing the density of the other scale image until a predetermined density is reached. Exists in the device.

  According to the second aspect of the present invention, the switching means reduces the density of one scale image stepwise, and at the same time switches the density of the other scale image stepwise, so that one scale image gradually disappears. At the same time, the other scale image is gradually displayed.

  According to a third aspect of the present invention, the pointer moving means rotates the pointer around the rotation axis, and the scale image is displayed on the display means along an arc centered on the rotation axis. The switching means displays the other scale image scaled on the inner peripheral side of the one scale image in response to the input of the switching command, and then gradually increases the scale of the other scale image. 3. The pointing device according to claim 2, wherein the scale image is switched.

  According to the invention described in claim 3, after the switching means displays the other scale image scaled on the inner peripheral side of one scale image in response to the input of the switching command, the scale of the other scale image is staged. Since the scale images are switched by enlarging them, the two images do not overlap even if two scale images having different scales are displayed simultaneously by switching.

  According to a fourth aspect of the present invention, the switching means is stepwise until the scale of the one scale image becomes equal to the scale of the other scale image so that the indicated position of the pointer on the one scale image does not move. The pointing device according to claim 1, wherein the scale image is switched by changing to the point.

  According to the invention of claim 4, the switching means changes stepwise until the scale of one scale image becomes equal to the scale of the other scale image so that the indicated position of the pointer on one scale image does not move. Switch the scale image. As a result, it is possible to switch from one scale image to the other scale image so that the indicated position of the pointer on one scale image matches the indicated position of the pointer on the other scale image. Thereby, one scale image can be switched gradually closer to the scale of the other scale image.

  According to a fifth aspect of the present invention, after the switching unit switches from the one scale image to the other scale image, the second scale image is positioned at a predetermined position on the display unit. The pointing device according to any one of claims 1 to 4, further comprising a pointer / scale moving means for moving the other scale image.

  According to the fifth aspect of the present invention, the pointer / scale moving means is switched from one scale image to the other scale image, and then the other scale image is set to a predetermined position on the display means. At the same time, the other scale image is moved. Therefore, the other scale image can be displayed at a predetermined position on the display means, that is, at an optimum position.

  According to a sixth aspect of the present invention, the pointer and the other scale image are blinked while the pointer and the other scale image are being moved by the pointer / scale moving means, or the display means is being switched. 6. The pointing device according to claim 5, further comprising notification means for displaying.

  According to the sixth aspect of the present invention, the notifying means blinks the pointer and the other scale image while the pointer and the other scale image are moved by the pointer / scale moving means, or is switched to the display means. Is displayed. Therefore, it is possible to notify the user that the movement of the pointer and the other scale image is caused by the switching of the scale image.

  According to the seventh aspect of the present invention, the display means for displaying the scale image indicated by the pointer, the input means for inputting the measurement target value detected by the sensor, and the measurement target value on the scale image are indicated. And a switching means for switching from one scale image displayed on the display means to the other scale image among at least two scale images having different scales according to a switching command. In the pointing device, the switching unit gradually decreases the density of the one scale image until the one scale image disappears from the display unit in response to the input of the switching command, and at the same time, on the display unit. The other scale image is displayed, and the scale image is switched by gradually increasing the density of the other scale image until a predetermined density is reached. It consists in pointing device to.

  According to the seventh aspect of the present invention, the switching means reduces the density of one scale image stepwise, and at the same time switches the density of the other scale image stepwise, so that one scale image gradually disappears. At the same time, the other scale image is gradually displayed.

  As described above, according to the first aspect of the present invention, since the pointing position of the pointer does not change even when switching from one scale image to the other scale image, the scale change without a sense of incongruity without receiving a sudden impression. Is possible.

  According to the second aspect of the present invention, since one scale image disappears gradually and the other scale image is gradually displayed, a scale change without a sense of incongruity is possible without receiving a more sudden impression. It becomes.

  According to the third aspect of the present invention, even if two scale images having different scales are displayed at the same time by switching, the two images do not overlap each other, so that the appearance during switching is good.

  According to the invention described in claim 4, since one scale image can be switched gradually closer to the scale of the other scale image, a scale change without a sense of incongruity is possible without receiving a sudden impression. It becomes.

  According to the invention described in claim 5, since the other scale image can be displayed at a predetermined position on the display means, that is, the optimum position, a scale change that does not give a sense of incongruity to the display of the scale image after switching is possible. It becomes possible.

  According to the sixth aspect of the invention, since it is possible to notify the user that the movement of the pointer and the other scale image is caused by the switching of the scale image, the movement of the pointer caused by the switching of the scale image is changed in the measurement target value. Will not be misrecognized.

  According to the seventh aspect of the present invention, since one scale image disappears gradually and the other scale image is gradually displayed, a scale change without a sense of incongruity is possible without receiving a sudden impression.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of the pointing device of the present invention. FIG. 2 shows an example of an image displayed on the liquid crystal display shown in FIG. As shown in the figure, the pointing device includes a TFT type liquid crystal display 10 (display means), a Y driver 21, an X driver 22, an LCD power source 23, a graphic controller 24, a central processing unit (CPU). 25).

  The liquid crystal display 10 has Y rows and X columns of liquid crystal elements arranged in a matrix, and a surface light source (none of which is shown) provided on the back of the Y rows and X columns of liquid crystal elements. Yes. Each liquid crystal element is sequentially provided with R (red), G (green), and B (blue) color filters CF. The liquid crystal display 10 is disposed on, for example, a vehicle control panel. As shown in FIG. 2, the liquid crystal display 10 has a fuel meter image 31 indicating the remaining amount of fuel in the vehicle, a speedometer image 32 indicating the speed of the vehicle, a tachometer image 33 indicating the engine speed of the vehicle, and a water temperature. A thermometer image 34, a travel distance display image 35, a shift display image 36, a warning image 37, and the like are displayed.

The Y driver 21 is connected to a Y row electrode E _Y provided at one end of the liquid crystal element in each row. X driver 22 is connected to the X row electrode E _X provided at the other end of the liquid crystal element of each column. That is, the liquid crystal element is sandwiched between the Y-row electrode E _Y and X column electrode E _X.

  The Y driver 21 and the X driver 22 are supplied with power from the LCD power source 23. The LCD power source 23 generates a constant voltage for the Y driver 21, the X driver 22, and a graphic controller 24 described later from the battery voltage + B. The Y driver 21 and the X driver 22 are controlled by a graphic controller 24.

  An ignition (IGN) switch is connected to the CPU 25 via an input / output terminal (I / O) 27. A CPU power supply 26 is connected to each of the Vcc terminal, RST terminal, and SLP terminal of the CPU 25. The CPU power supply 26 generates a power supply voltage for the CPU 25 from the battery voltage + B and supplies the power supply voltage to the Vcc terminal of the CPU 25. The CPU 25 operates by the power supply voltage from the Vcc terminal.

  The CPU power supply 26 outputs a reset command to the RST terminal of the CPU 25. In response to this reset command, the CPU 25 outputs a reset signal RST to the graphic controller 24. In response to the reset signal RST, the graphic controller 24 resets (erases) the image displayed on the liquid crystal display 10. When the IGN switch is turned off, the CPU 25 outputs a sleep command to the CPU power supply 26 from the SLP terminal. In response to the sleep command, the CPU power supply 26 lowers the power supply voltage supplied to the Vcc terminal of the CPU 25 to place the CPU 25 in the sleep (power saving) mode.

  Vehicle data is input to the CPU 25 via the I / O 28. The vehicle data is data transmitted from another CPU capable of CAN communication with the CPU 25. The vehicle data includes data such as vehicle speed and engine speed (measurement target value).

  An EEPROM 29 is connected to the CPU 25. The EEPROM 29 stores various data such as image data such as pointer image data, memory image data, background image data, and warning image data.

  A scale change switch 30 is connected to the CPU 25. The scale change switch 30 is a switch operated by the user when it is desired to switch the scale image displayed on the liquid crystal display 10 between a normal scale image and an enlarged scale image (at least two scale images having different scales). . The enlarged scale image is a scale image whose scale is larger than that of the normal scale image.

  The display operation of the pointing device having the above-described configuration will be described below. The CPU 25 reads the image data such as the pointer image data, the normal scale image data, the enlarged scale image data, the background image data, and the warning image data from the EEPROM 29, and stacks the read image data to layer-structured composite image data. To process. Then, the CPU 25 outputs the processed composite image data to the graphic controller 24.

The graphic controller 24 converts the composite image data into RGB signals, gradation data, and the like, and drives the Y driver 21 and the X driver 22 according to the RGB signals and gradation data. Specifically, the graphic controller 24 outputs a vertical scanning signal to the Y driver 21. The Y driver 21 sequentially selects one of the Y row electrodes E _Y in synchronization with the vertical scanning signal so that a voltage can be applied to the liquid crystal element connected to the selected Y row electrode E _Y. deep.

The graphic controller 24 outputs a horizontal synchronization signal to the X driver 22 and outputs an RGB signal and gradation data to the X driver 22 in synchronization with the horizontal synchronization signal. X driver 22 sequentially selects one of the X row electrode E _X in synchronization with the horizontal synchronizing signal, RGB signals, according to the gradation data to the liquid crystal element connected to the selected X row electrode E _X Apply voltage. That is, the intersection between the row selected by the Y driver 21 and the column selected by the X driver 22 is in a display state corresponding to the RGB signal and the gradation data. The Y driver 21 and the X driver 22 sequentially apply voltages corresponding to the RGB signals and the gradation data to all the liquid crystal elements in the X rows and the Y columns, so that an image corresponding to the composite image data is displayed on the liquid crystal display. 10 is displayed.

  Details of the operation of the pointing device described in the above outline will be described below with reference to flowcharts showing processing procedures of the CPU 25 in FIGS. The CPU 25 starts an operation in response to turning on of the IGN switch and performs initialization (not shown). Thereafter, the CPU 25 performs a normal instruction process shown in FIG. In the normal instruction process, the CPU 25 first functions as input means, inputs vehicle data via the I / O 28, and reads the vehicle speed, engine speed (measurement target value), etc. included in the input vehicle data. (Step S1).

  Next, the CPU 25 stacks the pointer image data, the scale image data, and the background image data on the basis of the read vehicle speed, engine speed, and the like to generate layered composite image data, which is not shown in the RAM (memory). Image data to be stored in the composite image area of (means) (step S2). Here, the CPU 25 stacks image data stored in advance in the scale image area in the RAM as scale image data. As a result of the initialization, data corresponding to the normal scale image 12 is stored in the scale image area. Further, the CPU 25 generates and stacks pointer image data that indicates measurement target values such as the vehicle speed and the engine speed on the scale image.

  Thereafter, the CPU 25 outputs the composite image data stored in the composite image area to the graphic controller 24 (step S3). If the scale change flag F1 is not on (N in step S4), the process returns to step S1. As a result, as shown in FIG. 2, the liquid crystal display 10 has a fuel meter image 31, a speedometer image 32, a tachometer image 33, a thermometer image 34, a travel distance display image 35, a shift display image 36, and a warning image 37. Is displayed.

  As shown in FIG. 7A, the tachometer image 33 includes a background image 11, a normal scale image 12 superimposed on the background image 11, and a pointer image 13 superimposed on the normal scale image 12. Yes.

  By repeating the above steps S1 to S3, the CPU 25 functions as a pointer moving means and moves the pointer image 13 so as to indicate the engine speed (measurement target value) input in step S1 on the normal scale image 12. The CPU 25 rotates about the rotation axis of the pointer image 13. The normal scale image 12 and an enlarged scale image 15 described later are displayed along an arc centered on the rotation axis of the pointer image 13. The center of the circular background image 11 is located on the rotation axis of the pointer image 13.

  On the other hand, if the scale change flag F1 is on (Y in step S4), the CPU 25 starts the first scale change process (step S5) and ends the normal instruction process. The scale change flag F1 is a flag that is turned on when the scale change switch 30 is operated. Alternatively, the flag may be turned on when the measurement range of the engine speed is divided into a plurality of regions (for example, a low rotation region and a high rotation region) and the region of the target measurement value is changed.

  In the first scale change process shown in FIG. 4, the CPU 25 first functions as input means, inputs vehicle data via the I / O 28, and the vehicle speed, engine speed (measurement target value) included in the input vehicle data. ) Is read (step S6).

  Thereafter, the CPU 25 functions as a notification unit, and performs a display process of superimposing the character image 14 of “scale change” on the image data (= normal scale image 12) stored in the scale image area and storing it in the scale image area. Perform (step S7). The CPU 25 further superimposes the change scale image (= enlarged scale image 15) on the image data (= normal scale image 12 + character image 14) stored in the scale image area and stores it in the scale image area (step S8). .

  Here, of the normal scale image 12 and the enlarged scale image 15, the one currently displayed on the liquid crystal display 10 is the current scale image (= one scale image), and the one not displayed is the change scale image (= The other scale image). FIG. 7 shows a display example when the normal scale image 12 that is the current scale image is switched to the enlarged scale image 15 that is the change scale image.

  The step S8 will be described in detail. As shown in FIG. 7B, the enlarged scale image 15 reduced in size is superimposed on the inner circumference side of the normal scale image 12. At this time, the enlarged scale image 15 scaled so that the pointer image 13 indicates the same value on both the normal scale image 12 and the enlarged scale image 15 is superimposed. Further, the enlarged scale image 15 is overlaid so that the contrast with the background image 11 is smaller than a predetermined value.

  Thereafter, the CPU 25 lays the pointer image data, the scale image data, and the background image data on the basis of the read vehicle speed, engine speed, etc. to generate layered composite image data, and stores it in the composite image area. Image data processing is performed (step S9). Then, the CPU 25 outputs the composite image data stored in the composite image area to the graphic controller 24 (step S10). As a result, as shown in FIG. 7B, an enlarged scale image 15 slightly reduced in scale is displayed on the inner circumference side of the normal scale image 12. The scaled scale image 15 is displayed along an arc centered on the rotation axis of the pointer image 13.

  Then, after starting the second scale change process shown in FIG. 5 (step S11), the CPU 25 ends the first scale change process. In the second scale change process, the CPU 25 first acts as an input means, inputs vehicle data via the I / O 28, and sets the vehicle speed, engine speed (measurement target value), etc. included in the input vehicle data. An input process for reading is performed (step S12).

  Thereafter, the CPU 25 increases the density of the change scale image (= enlarged scale image 15) stored in the scale image area by a certain amount and scales the scaled change scale image (= enlarged scale image 15). A certain amount is increased (steps S13 and S14). Then, the CPU 25 reduces the density of the current scale image (= normal scale image 12) stored in the scale image area by a certain amount (step S16). Here, increasing or decreasing the density means increasing or decreasing the contrast with the background image 11.

  Next, the CPU 25 generates layered composite image data by laminating the pointer image data, the scale image data, and the background image data based on the read vehicle speed, engine speed, and the like. Then, the image data to be stored in the composite image area is processed (step S16). Thereafter, the CPU 25 outputs the composite image data to the graphic controller 24 (step S17).

  If the steps S13 to S15 are not repeated N times (N in step S18), the CPU 25 returns to step S12 again. By repeatedly performing steps S13 to S15, the current scale image (= normal scale image 12) displayed on the liquid crystal display 10 becomes gradually thinner. At the same time, the change scale image (= enlarged scale image 15) becomes gradually darker and the scale becomes gradually larger and approaches the outer periphery of the background image 11. In step S14, the CPU 25 changes the scale image so that the pointer image 13 indicates the same value on both the current scale image (= normal scale image 12) and the change scale image (= enlarged scale image 15). = The scale of the enlarged scale image 15) is increased by a certain amount.

  Then, when Steps S13 to S15 are repeated N times (Y in Step S18), the CPU 25 starts the third scale change process shown in FIG. 6 (Step S19) and ends the second scale change process. At this time, as shown in FIG. 7C, the enlarged scale image 15 is not scaled and is displayed along the outer periphery of the background image 11. Further, the contrast between the enlarged scale image 15 and the background image 11 reaches a predetermined value, that is, the density reaches a predetermined density, and the enlarged scale image 15 is clearly visually recognized.

  On the other hand, the contrast between the normal scale image 12 and the background image 11 disappears, and the display of the normal scale image 12 disappears. In the third scale change process, the CPU 25 first functions as input means, inputs vehicle data via the I / O 28, and reads the vehicle speed, engine speed (measurement target value), etc. included in the input vehicle data. An input process is performed (step S20).

  The CPU 25 functions as a pointer / scale moving means and, as shown in FIG. 7D, the change scale image (= enlarged) together with the pointer image 13 so that the change scale image (= enlarged scale image 15) is directed to a predetermined final position. The scale image 15) is rotated by a certain amount and stored in the scale image area (step S21). Thereafter, the CPU 25 generates layered composite image data by laminating the pointer image data, the scale image data, and the background image data based on the read vehicle speed, the engine speed, and the like. ) Is processed (step S22), and the composite image data is output to the graphic controller 24 (step S23).

  As a result of repeating steps S20 to S23, when the change scale image (= enlarged scale image 15) reaches the final position (Y in step S24), the character image 14 of “scale change” is deleted and the scale change flag F1. Is turned off (steps S25 and S26), the normal instruction process is started again (step S27), and the third scale change process is terminated.

  In the above-described embodiment, the example of switching from the normal scale image 12 to the enlarged scale image 15 has been described. However, the case of switching from the enlarged scale image 15 to the normal scale image 12 is similarly performed. That is, the reduced normal scale image 12 is slightly displayed on the inner circumference side of the enlarged scale image 15. Thereafter, the density of the enlarged scale image 15 gradually decreases and disappears from the liquid crystal display 10. At the same time, the scale of the normal scale image 12 is gradually increased to approach the outer periphery of the background image 11 and the density is gradually increased. As a result, the enlarged scale image 15 is switched to the normal scale image 12.

  According to the above-described embodiment, as is clear from a comparison between FIGS. 7A and 7C, the CPU 25 functions as a switching unit, and the pointer on the current scale image (= normal scale image 12). The current scale image is switched to the change scale image so that the designated position of the image 13 matches the designated position on the pointer image 13 on the change scale image (= enlarged scale image 15). As a result, even if the current scale image is switched to the change scale image, the indicated position of the pointer image 13 does not change, so that a scale change without a sense of incongruity is possible without receiving a sudden impression.

  Further, according to the above-described embodiment, the CPU 25 determines the density of the current scale image until the current scale image (= normal scale image 12) disappears from the liquid crystal display 10 in response to the scale change flag F1 being turned on (= switching command). The scale image is reduced stepwise and at the same time a change scale image (= enlarged scale image 15) is displayed on the liquid crystal display 10, and the density of the change scale image is increased stepwise until a predetermined density is reached. Has been switched. As a result, the current scale image gradually disappears and at the same time the change scale image is gradually and clearly displayed, so that a scale change without a sense of incongruity is possible without receiving a more sudden impression.

  According to the above-described embodiment, the CPU 25 displays the change scale image (= enlarged scale image 15) scaled on the inner circumference side of the current scale image (= normal scale image 12) in response to the scale change flag F1 being turned on. Thereafter, the scale image is switched by gradually increasing the scale of the change scale image. Thereby, even if the normal scale image 12 and the enlarged scale image 15 are displayed simultaneously by switching, both images do not overlap and the appearance during switching is improved.

  According to the above-described embodiment, after the CPU 25 is switched from the current scale image (= normal scale image 12) to the change scale image (= enlarged scale image 15), the change scale image is predetermined on the liquid crystal display 10. The change scale image is moved together with the pointer image 13 so that the final position is reached. As a result, the change scale image can be displayed at a predetermined final position on the liquid crystal display 10, that is, the optimum position, so that the scale change without discomfort can be made in the display of the scale image after switching.

  According to the embodiment described above, as shown in FIG. 7C, the CPU 25 is switching to the liquid crystal display 10 while the pointer image 13 and the change scale image (= enlarged scale image 15) are moving. A character image 14 of “scale change” is displayed. Therefore, it is possible to notify the user that the movement of the pointer image 13 and the change scale image is caused by the switching of the scale image, and the movement of the pointer image 13 caused by the change of the scale image is erroneously recognized as a change in the measurement target value. Disappear.

  According to the above-described embodiment, as shown in FIG. 7B, the normal scale image 12 and the enlarged scale image 15 are simultaneously displayed during switching, and the density of the normal scale image 12 is decreased stepwise. Although the scale image is switched by increasing the scale and density of the enlarged scale image 15 in stages, the present invention is not limited to this.

  For example, when switching from the normal scale image 12 to the enlarged scale image 15, the order may be switched in the order of FIG. 8 (A) → FIG. 8 (B) → FIG. 8 (C). As shown in the figure, the CPU 25 uses the scale of the normal scale image 12 as the scale of the enlarged scale image 15 so that the indicated position of the pointer image 13 on the normal scale image 12 does not move (that is, centering on the pointer image 13). The scale images are switched in steps until they are equal. Conversely, when switching from the enlarged scale image 15 to the normal scale image 12, the order is switched in the order of FIG. 8 (C) → FIG. 8 (B) → FIG. 8 (A). As shown in the figure, the CPU 25 reduces the scale of the enlarged scale image 15 stepwise until it becomes equal to the scale of the normal scale image 12 so that the indicated position of the pointer image 13 on the enlarged scale image 15 does not move. The scale image is switched.

  Although the normal scale image 12 and the enlarged scale image 15 overlap, the enlarged scale image 15 is displayed along the outer periphery of the background image 11 from the beginning without reducing the scale, and the density of the normal scale image 12 is stepwise. Simultaneously with the reduction, the density of the enlarged scale image 15 may be increased stepwise.

  Further, in the above-described embodiment, the tachometer image 33 is displayed on the liquid crystal display 10 in the order of FIG. 7 (A) → FIG. 7 (B) → FIG. 7 (C). It is not limited. For example, the display shown in FIG. 7B may be skipped, and the tachometer image 33 may be displayed on the liquid crystal display 10 in the order of FIG. 7A → FIG. 7C.

  In the above-described embodiment, the pointer image 13 displayed on the liquid crystal display 10 is used as a pointer, but the present invention is not limited to this. For example, a pointer driven by a motor or the like may be used as the pointer.

  The present invention is not limited to the above-described embodiment. For example, the density of the current scale image is decreased stepwise until the current scale image disappears from the liquid crystal display 10, and at the same time, the change scale image is displayed on the liquid crystal display 10, and the change scale image is displayed until a predetermined density is reached. It is only necessary to increase the density of the change scale image from the current scale image so that the indicated position of the pointer image 13 on the current scale image matches the indicated position of the pointer image 13 on the change scale image. There is no need.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

It is a block diagram which shows one Embodiment of the instruction | indication apparatus of this invention. An example of the image displayed on the liquid crystal display shown in FIG. 1 is shown. It is a flowchart which shows the process sequence of CPU in an instruction | indication process. It is a flowchart which shows the process sequence of CPU in a 1st scale change process. It is a flowchart which shows the process sequence of CPU in a 2nd scale change process. It is a flowchart which shows the process sequence of CPU in a 3rd scale change process. A display example is shown when the normal scale image that is the current scale image is switched to the enlarged scale image that is the change scale image. The other example of a display is shown when it switches from the normal scale image which is a current scale image to the enlarged scale image which is a change scale image. It is a figure which shows an example of the conventional indicator.

Explanation of symbols

10 Liquid crystal display (display means)
12 Normal scale image (scale image)
13 Pointer image (pointer)
15 Enlarged scale image (scale image)
25 CPU (input means, pointer moving means, switching means, pointer / scale moving means, notification means)

Claims (7)

Display means for displaying a scale image instructed by a pointer, input means for inputting a measurement target value detected by a sensor, and pointer movement for moving the pointer to indicate the measurement target value on the scale image And a switching device for switching from one scale image displayed on the display unit to the other scale image among at least two scale images having different scales according to a switching command.
The switching means switches from the one scale image to the other scale image so that the indicated position of the pointer on the one scale image matches the indicated position of the pointer on the other scale image. A pointing device characterized by.   In response to the input of the switching command, the switching means gradually reduces the density of the one scale image until the one scale image disappears from the display means, and at the same time, the other scale image on the display means. 2. The pointing device according to claim 1, wherein the scale image is switched by gradually increasing the density of the other scale image until a predetermined density is reached. The pointer moving means rotationally moves the pointer around a rotation axis;
The scale image is displayed on the display means along an arc centered on the rotation axis,
Then, after the switching means displays the other scale image scaled to the inner circumference side of the one scale image in response to the input of the switching command, the scale of the other scale image is increased stepwise. The pointing device according to claim 2, wherein the scale image is switched.   The switching means changes the scale image of the one scale image stepwise until it becomes equal to the scale of the other scale image so that the indicated position of the pointer on the one scale image does not move. The pointing device according to claim 1, wherein the pointing device is switched.   After the switching means is switched from the one scale image to the other scale image, the other scale image is moved together with the pointer so that the other scale image is at a predetermined position on the display means. The pointing device according to any one of claims 1 to 4, further comprising a pointer / scale moving means.   It further has a notifying means for blinking the pointer and the other scale image while moving the pointer and the other scale image by the pointer / scale moving means, or displaying the fact that the pointer is being switched on the display means. The pointing device according to claim 5. Display means for displaying a scale image instructed by a pointer, input means for inputting a measurement target value detected by a sensor, and pointer movement for moving the pointer to indicate the measurement target value on the scale image And a switching device for switching from one scale image displayed on the display unit to the other scale image among at least two scale images having different scales according to a switching command.
In response to the input of the switching command, the switching means gradually reduces the density of the one scale image until the one scale image disappears from the display means, and at the same time, the other scale image on the display means. Is displayed, and the scale image is switched by gradually increasing the density of the other scale image until a predetermined density is reached.

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