JP4774794B2 - Display device - Google Patents

Description

The present invention relates to a display device, for more possible to adjust the image quality such as the adjustable signal by operating the knob.

  A rotary adjustment device (hereinafter sometimes referred to as a volume) that has been used as a user interface for a long time has excellent ergonomic features such as being easy to grasp the adjustment amount sensuously. Therefore, even in the era of digitization as in today, the rotary volume is widely used in various industrial fields (see Patent Document 1). For example, in a commercial television monitor, a rotary volume is used to adjust image quality such as phase (hue), chroma (saturation), contrast, and brightness.

A general rotary volume includes, for example, a variable resistor whose resistance value changes as the shaft rotates. When a constant DC voltage is applied to both ends of the variable resistor, a DC voltage corresponding to the rotation angle of the shaft is generated from the sliding terminal. By converting this DC voltage into a digital signal by an analog-digital converter, a digital signal corresponding to the rotation angle of the shaft can be obtained.
JP 2002-267439 A

  When the positive / negative adjustment with respect to the reference value is performed using the rotary volume, the knob is normally used by rotating the knob left and right with respect to the reference midpoint. In this case, since it is necessary for the user to know whether or not the rotation angle of the knob is at the middle point, in general, the rotation angle of the knob is visually represented by marking each of the volume mounting panel and the knob. ing.

  On the other hand, there is also a volume that represents the rotation angle of the knob by discontinuously changing the operation feeling of the knob near the midpoint. Such a volume is provided with a mechanism (click mechanism) that changes the load of the knob rotation operation discontinuously when the knob rotation angle passes near the middle point, for example. Thereby, since the user can grasp the rotation angle of the knob only by the feeling at hand, the operability is further improved than the method of visually grasping the rotation angle.

  However, the resistance value of the variable resistor has a relatively large variation. For this reason, the output signal of the volume at the mechanical middle point where the click mechanism operates is deviated from the theoretical center value. Usually, in order to correct such a deviation, calibration is performed on the output signal of the volume. In other words, the relationship between the rotation angle of the knob and the output signal of the volume is measured, and a function for converting the output signal of the volume into an appropriate signal corresponding to the rotation angle of the knob is determined based on the measurement result. The A signal generated by the variable resistor is converted based on this function and is treated as an output signal of the volume.

FIG. 8 is a diagram illustrating an example of a function for converting an output signal in a general rotary volume with a click mechanism.
In the graph shown in FIG. 8, the horizontal axis represents the signal S1 generated by the variable resistor, and the vertical axis represents the volume output signal S2.

The signal S1 generated by the variable resistor is, for example, a minimum value Mn1 when the knob is fully rotated counterclockwise, a maximum value Mx1 when the knob is fully rotated clockwise, and a value C1 at the middle point where the click mechanism is activated. Have
On the other hand, the volume output signal S2 is the ideal value when the knob is fully turned counterclockwise, the minimum value “Mn2”, when the knob is fully turned clockwise, the maximum value “Mx2”, and the click mechanism is activated. Has a value C2 at the midpoint.
In this case, in the range of “Mn1 ≦ S1 ≦ C1”, for example, a linear function represented by the following equation is used.

[Equation 1]
S2 = (C2-Mn2) × (S1-Mn1) / (C1-Mn1) + Mn2 (1)

  In the range of ‘C1 ≦ S1 ≦ Mx1’, for example, a linear function represented by the following equation is used.

[Equation 2]
S2 = (Mx2-C2) * (S1-C1) / (Mx1-C1) + C2 (2)

  As shown in the equations (1) and (2), the function for converting the output signal in the rotary volume with a click mechanism is generally at a point where the click mechanism operates (hereinafter sometimes referred to as a click point). It is determined using the value C1 of the signal S1 generated by the variable resistor.

  However, due to the problem of mechanical accuracy, it is difficult to set the click point to exactly one point, and a certain amount of “play” actually occurs. For this reason, even when the knob is set to the click point, the rotation angle of the knob cannot be accurately set to the middle point due to the presence of the “play”, and the volume output signal S2 is deviated from the center value. .

  In general, the click mechanism has a mechanically unstable transition section during the transition from the normal section to the above-mentioned "play" section, and it is difficult to keep the knob in this transition section. . Therefore, the signal output from the volume in the transition section becomes unstable and cannot be used for device adjustment. That is, there is an inconvenience that an unstable signal that cannot be used for device adjustment is generated on both sides of the click point.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a display device that adjusts image quality while preventing an unstable signal from being generated when the load on the knob operation changes discontinuously. It is to provide.

A display device according to a first aspect of the present invention includes an image display unit capable of adjusting an image quality, a plurality of adjustment units that generate a signal for adjusting the image quality by operating each knob, and the plurality of adjustments. A control unit that changes the image quality of the image display unit based on a plurality of signals generated from the unit, and the adjustment unit includes the knob, and changes according to an operation amount of the knob. a signal generating means for generating a signal, pre-SL signal more the generated first signal to the generating means, a second signal utilized with signals of other of the adjustment portion for adjusting the image quality in the controller The signal conversion means for converting to the operation of the knob and the operation amount of the knob when the operation amount of the knob changes between a predetermined range which is a part of the operation range of the knob and outside the predetermined range. By changing the load discontinuously, Click means for generating a mechanical click feeling with respect to the operation of the eyelids, and when the knob is operated within the predetermined range, the signal conversion means performs the operation according to the operation within the range. The second signal having a constant value is output even though the first signal input from the signal generating means changes.

The “knob operation” described here indicates an operation that causes a mechanical displacement of the knob. For example, an operation of rotating the knob or an operation of moving the knob is included in the “knob operation”.
The “knob operation amount” described here indicates the magnitude of the mechanical displacement of the knob with respect to a predetermined reference point, which is caused by the operation of the knob described above. For example, the “rotation amount of the knob” includes the rotation angle and movement distance of the knob from a certain reference point.

  According to the present invention, the first signal that changes in accordance with the operation of the knob is converted into the second signal that changes in accordance with the operation of the knob in the signal conversion means. However, when the operation amount of the knob is within the predetermined range in which the load for the operation of the knob changes discontinuously, the first signal is a signal having a predetermined value that does not change according to the operation of the knob. Converted.

  According to the present invention, in a range where the load on the knob operation changes discontinuously, a signal having a predetermined value that does not change according to the knob operation is generated. Therefore, an unstable signal is generated in this range. Can be prevented. This also facilitates image quality adjustment.

FIG. 1 is a diagram showing an example of an appearance when a display device according to an embodiment of the present invention is viewed from the front.
A display device 1 shown in FIG. 1 is provided with a screen 2 of a display unit such as a liquid crystal display panel or an organic EL panel in the center of the front surface thereof. Rotary knobs 5 </ b> A to 5 </ b> D, an operation key group 4 used for various controls of the display device 1, and a power switch 3 are arranged.

  The rotary volume knobs 5A to 5D are used for adjusting the phase (hue), chroma (saturation), contrast, and luminance, respectively.

FIG. 2 is a diagram illustrating an example of the configuration of the display device 1.
The display device 1 illustrated in FIG. 2 includes a control unit 10, an image display unit 20, a storage unit 30, an operation unit 40, and an interface unit 50.
The control unit 10 is an example of a control unit of the present invention.
The image display unit 20 is an example of the image display unit of the present invention.

The control unit 10 executes various controls and processes related to the overall operation of the display device 1.
For example, the control unit 10 performs predetermined image signal processing on the image signal input from the interface unit 50, converts the image signal into an image signal of a predetermined format, and supplies the image signal to the image display unit 20. Further, in accordance with various commands and signals input from the operation unit 40, setting of an image display format in the image display unit 20, adjustment of image quality, and the like are performed.

  The control unit 10 includes, for example, a computer, reads a program code stored in the storage unit 30, and executes processing according to the program code.

  The image display unit 20 is configured by a display device such as a liquid crystal display panel, an organic EL panel, or a CRT, for example, and displays a moving image or a still image corresponding to an image signal supplied from the control unit 10.

The storage unit 30 stores temporary data generated during the process of the control unit 10, constant data used for the process, computer program code of the control unit 10, and the like.
For example, the storage unit 30 stores constant data used in the signal conversion unit 404 of the adjustment unit (FIG. 3) described later.

  The operation unit 40 is a command for controlling the display device 1 or an adjustment signal in response to a user operation on the operation mechanisms such as the rotary volumes 5A to 5D, the operation key group 4, and the power switch 3 shown in FIG. Is generated.

  The interface unit 50 inputs image signals of various formats input as analog signals or digital signals, and supplies them to the control unit 10.

FIG. 3 is a diagram illustrating an example of the configuration of the adjustment device according to the present embodiment, and illustrates an example of the adjustment device applied to a rotary volume.
The operation unit 40 has, for example, four rotary volumes shown in FIG. 3, and these four rotary volumes generate signals S2 corresponding to the rotary operation of the knobs (5A to 5D), respectively.

The rotary volume shown in FIG. 3 has a variable resistor 401, a constant voltage source 402, an analog-digital converter 403, and a signal conversion unit 404.
A circuit including the variable resistor 401, the constant voltage source 402, and the analog-digital converter 403 is an example of the signal generating means of the present invention.
The signal conversion unit 404 is an example of a signal conversion unit of the present invention.

The variable resistor 401 includes a resistor 401A having a constant resistance value, and a contact portion 401B that contacts the resistor 401A and slides on the resistor 401A in accordance with the rotation operation of the knob.
Resistor 401A is connected between nodes N1 and N2, and contact 401B is connected to node N3.
When the contact 401B slides on the surface of the resistor 401A according to the knob rotation operation, the ratio between the resistance value between the nodes N1-N3 and the resistance value between the nodes N3-N2 changes.

  The constant voltage source 402 applies a constant voltage between the nodes N1 and N2.

  The analog-digital converter 403 converts the voltage Sp generated between the node N3 and the node N1 into a digital signal S1.

  The signal conversion unit 404 converts the signal S1 output from the analog-digital converter 403 into a signal 2 that changes in accordance with the rotation operation of the knob. However, when the rotation angle of the knob is within a predetermined range, the signal S1 is converted into a signal S2 having a predetermined value C2 that does not change according to the operation of the knob.

  In the predetermined range, the load for the rotation operation of the knob changes discontinuously by the function of the mechanism as shown in FIG. Hereinafter, this discontinuous change in load may be referred to as “click”.

  Here, the mechanism for generating the click will be described with reference to FIGS.

4 and 5 are views showing an example of the mechanical structure of the rotary volume shown in FIG.
FIG. 4 shows a cross section when the rotary volume is cut along the center of the rotary shaft 507 of the variable resistor 401. FIG. 5 is an enlarged view of a part of the cross section shown in FIG.

4 and 5, the substrate 502 is an example of the substrate of the present invention.
The surface 503 of the substrate 502 is an example of the sliding surface of the present invention.
The sliding part 504 is an example of the sliding part of the present invention.
The step portions 505A and 505B are examples of the step portion of the present invention.

  The variable resistor 401 is fixed to the back surface 503B of the substrate 502 by a fixing tool (not shown). The rotating shaft 507 of the variable resistor 401 passes through a hole 506 provided in the substrate 502 and protrudes from the surface 503A of the substrate 502. The knob 501 is fixed to the protruding portion of the rotating shaft 507.

  A recess 505 is formed on the surface 503 of the substrate 502 covered with the knob 501 at a position away from the center of the rotation shaft 507 by a predetermined distance. Further, a guide portion 509 is formed on the surface 508 of the knob 501 facing the surface 503 at a position away from the center of the rotation shaft 507 by the predetermined distance. The guide portion 509 is a recess dug in a direction perpendicular to the surface 503A, and the sliding portion 504 moves up and down in the figure along this recess. A spring 510 is sandwiched between the bottom surface of the sliding portion 504 and the bottom surface of the guide portion 509, and urges the sliding portion 504 in the vertical direction toward the surface 503A.

  The sliding portion 504 is pressed against the surface 503A by the bias of the spring 510. Therefore, when the knob 501 is rotated, the sliding portion 504 slides in a circle while contacting the surface 503A. Since the concave portion 505 is formed on the circular orbit, the sliding portion 504 contacts the step portion 505A or 505B of the concave portion 505 when the rotation angle of the knob 501 enters a predetermined range. Since the sliding portion 504 is pressed against the surface 503A by the spring 510, when it comes into contact with the stepped portion 505A or 505B, a rotational force acts in a direction to slide down the slope. As a result, in this predetermined range, the load for the rotation operation of the knob 501 changes discontinuously.

FIG. 6 is a diagram illustrating an example of the range of rotation angles at which clicks occur.
When the rotation angle is in the range of “P1” to “P2” (first range) and in the range of “P3” to “P4” (second range), the sliding portion 504 makes the surface 503A constant. Sliding with a load of.
On the other hand, when the rotation angle is in the range of “P2” to “P3”, the sliding portion 504 falls into the recess 505.

In the range of the rotation angles P2 to P3, “A1” and “A2” indicate sections where the sliding portion 504 slides down the slopes 505A and 505B. 'A3' indicates a section in which the sliding portion 504 comes down the slope and contacts the bottom surface 505C.
In the sections A <b> 1 and A <b> 2, a force that tries to slide down on the bottom surface 505 </ b> C of the recess 505 acts on the sliding portion 504. Therefore, when the rotation angle of the knob 501 passes through these sections, a discontinuous change of the load, that is, a click occurs. The sections A1 and A2 are mechanically unstable sections, and the rotation angle cannot be kept stable in this section. Therefore, even if the knob 501 is set to the sections A1 and A2, the rotation angle settles in the section A3.

Heretofore, the mechanism that generates a click and the function thereof have been described in the present embodiment.
When the rotation angle of the knob 501 is within the range (P2 to P3) in which such a click occurs, the signal conversion unit 404 outputs the signal S2 to a constant regardless of the rotation operation of the knob 501 as shown in FIG. Hold at value C2.

  FIG. 7 is a diagram illustrating an example of a function for converting a signal in the signal conversion unit 404. The horizontal axis indicates the signal S1, and the vertical axis indicates the signal S2.

In the example of FIG. 7, when the rotation angles are “P1”, “P2”, “P3”, and “P4” (see FIG. 6), the value of the output signal S1 of the analog-digital converter 403 is “Mn1”. , 'Cp1', 'Cp2', and 'Mx1'. The value Mn1 is the minimum value of the signal S1, and the value Mx1 is the maximum value of the signal S1.
When the value of the signal S1 is 'Mn1', 'Cp1', 'Cp2', 'Mx1', the signal conversion unit 404 sets the value of the signal S2 to 'Mn2', 'C2', 'C2', 'Mx2', respectively. Set to.

  When ‘Mn1 ≦ S1 ≦ Cp1’, the signal conversion unit 404 converts the signal S1 into the signal S2 based on, for example, a linear function (first function) represented by the following equation.

[Equation 3]
S2 = (C2-Mn2) × (S1-Mn1) / (Cp1-Mn1) + Mn2 (3)

  When ‘Cp2 ≦ S1 ≦ Mx1’, the signal conversion unit 404 converts the signal S1 into the signal S2 based on, for example, a linear function (second function) represented by the following equation.

[Equation 4]
S2 = (Mx2-C2) * (S1-Cp2) / (Mx1-Cp2) + C2 (4)

  On the other hand, when ‘Cp1 ≦ S1 ≦ Cp2’, the signal conversion unit 404 holds the signal S2 at a constant value C2 as shown in the following equation.

[Equation 5]
S2 = C2 (5)

That is, when the rotation angle of the knob 501 is in the range of “P1” to “P2”, the signal converter 404 converts the signal S1 into the signal S2 based on the first function (equation (3)), and the knob 501 Is in the range of “P3” to “P4”, the signal S1 is converted into the signal S2 based on the second function (equation (4)).
On the other hand, when the rotation angle of the knob 501 is in the range of “P2” to “P3”, the signal S2 is held at a constant value C2.

The first function (Equation (3)) is based on the values “Mn1” and “Cp1” of the signal S1 generated when the rotation angle of the knob 501 is actually set to “P1” and “P2”, and predetermined values. It is determined based on “Mn2” and “C2”.
The second function (Equation (4)) is based on the values “Cp2” and “Mx1” of the signal S1 generated when the rotation angle of the knob 501 is actually set to “P3” and “P4”, and predetermined values. It is determined based on “C2” Mx2 ”.

  Information on the first function and the second function (such as the slope and intercept of the linear function) determined by such calibration is written in advance in the storage unit 30 at the time of manufacturing, for example. The signal conversion unit 404 performs conversion from the signal S1 to the signal S2 based on the information of this function.

As described above, according to the present embodiment, the signal S1 that changes according to the rotation of the knob 501 is generated using the variable resistor 401 or the like. Further, when the rotation angle of the knob 501 is within a predetermined range (P2 to P3), a discontinuous change (click) of the load with respect to the rotation operation of the knob 501 occurs. Then, the signal S1 is converted into a signal S2 that changes according to the rotation operation of the knob in the rotation angle range (P1 to P2, P2 to P4) where the click does not occur, and the rotation angle range (P2 to P2) where the click occurs. In P3), the signal is converted into a signal S2 having a constant value C2 irrespective of the knob rotation operation.
As a result, even if the value of the signal S1 is unstable in the rotation angle range (P2 to P3) where the click occurs, the value of the signal S2 output as the conversion result can be kept stable. Therefore, the conventional problem that an unstable signal that cannot be used for device adjustment is generated in the vicinity of the click point is solved, and an accurate signal corresponding to the rotation angle of the knob 501 is stabilized even in the vicinity of the click point. Can occur.

  Even if there is a play section (A3) in the rotation angle range (P2 to P3) where the click occurs, the signal of constant value C2 is always affected without being affected by the fluctuation of the signal S1 in this play section (A3). S2 can be output. Therefore, the signal value C2 of the click point can be generated easily and accurately without performing a delicate operation of the knob 501. In general, the signal value C2 at the click point is frequently used for adjustment, and high accuracy is required compared with other points. Therefore, according to the present embodiment, adjustment of the device (for example, image quality adjustment in a display device) Becomes much easier and the operability is improved.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited only to said form.
That is, those skilled in the art may make various modifications, combinations, sub-combinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.

  For example, in the above-described embodiment, the signal conversion unit 404 converts the signal S1 into the signal S2 by a linear function, but the present invention is not limited to this. That is, the signal conversion unit may perform signal conversion using various functions other than the linear function.

  In the above-described embodiment, the signal conversion unit 404 performs signal conversion by performing numerical calculation based on a function expressed by a mathematical expression, but the present invention is not limited to this. For example, a conversion table that correlates the value of the signal S1 and the value of the signal S2 on a one-to-one basis may be prepared, and conversion from the signal S1 to the signal S2 may be performed with reference to the conversion table.

  The signal conversion unit 404 may be configured by hardware, or an equivalent function may be realized by software using a computer. In the latter case, the function of the signal conversion unit 404 may be realized using a computer of the control unit 10.

  In the above-described embodiment, an example of an adjustment device that generates a signal that changes in accordance with the rotation of the knob is given, but the present invention is not limited to this. For example, a method of sliding the knob linearly may be used, and the form of operation of the knob in the present invention is arbitrary.

  In the above-described embodiment, two step portions (505A and 505B) are provided to generate a click, but the present invention is not limited to this. That is, the number of step portions can be any number of one or more.

It is a figure which shows an example of the external appearance at the time of seeing the display apparatus which concerns on embodiment of this invention from the front. It is a figure which shows an example of a structure of the display apparatus which concerns on embodiment of this invention. It is a figure which shows one structural example of the rotary volume as an adjustment apparatus which concerns on embodiment of this invention. It is a figure which shows an example of the mechanical structure of the rotary volume shown in FIG. In FIG. 4, it is the figure which expanded and showed the part in connection with a sliding part and a level | step difference part. It is the figure which illustrated an example of the range which the discontinuous change of the load generate | occur | produces with respect to rotation operation of a knob. It is a figure which shows an example of the function which converts a signal in a signal conversion part. It is a figure which shows an example of the function which converts an output signal in the general rotary volume with a click mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Display apparatus, 2 ... Screen, 3 ... Power switch, 4 ... Operation key group, 5A-5D, 501 ... Knob, 10 ... Control part, 20 ... Image display part, 30 ... Memory | storage part, 40 ... Operation part, 50 DESCRIPTION OF SYMBOLS ... Interface part 401 ... Variable resistor 402 ... Constant voltage power supply 403 ... Analog-digital converter 404 ... Signal conversion part 502 ... Board | substrate 503A ... Surface (sliding surface) of the board | substrate 502, 504 ... Sliding Part, 505 ... concave part, 505A, 505B ... step part

Claims (4)

An image display with adjustable image quality;
A plurality of adjustment units for generating a signal for adjusting the image quality by operation of each knob ;
A control unit that changes the image quality of the image display unit based on a plurality of signals generated from the plurality of adjustment units;
Comprising
The adjustment unit is
Signal generating means for generating a first signal that has the knob and changes according to an operation amount of the knob ;
More the generated first signal before SL signal generation means, a signal conversion means for converting the said control unit to the second signal which is utilized with the signal of the other of the adjustment portion for adjusting the image quality,
When the operation amount of the knob changes between a predetermined range which is a part of the operation range of the knob and outside the predetermined range, the operation load for the operation of the knob is changed discontinuously. Click means for generating a mechanical click feeling with respect to the operation of the knob;
Have
The signal converting means includes
When the knob is operated within the predetermined range, the first signal input from the signal generating means is changed by the operation within the range, but the first value having a constant value is changed. 2 signal is output
Display device. The click means is
A sliding portion and a sliding contact surface provided in the signal generating means and in sliding contact with each other when the knob is operated;
A recess formed on the track of the sliding portion on the sliding contact surface and defining the predetermined range;
Claim 1 Symbol placement of the display device having a. The recess has an inclined surface;
The predetermined range includes
Display device according to claim 1, wherein is included a state in which the sliding portion corresponds to the inclined surface of the recess. The predetermined range is:
An intermediate part of the operating range of the knob,
The constant value is
The display device according to claim 1, wherein the display device has an intermediate value in a change range of the second signal .

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