JP2012199600A - Apparatus for watching television screen in supine posture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reflector device which form the image of a television screen at an optimum position where the elevation angle of sight line is close to 70°, and to provide a dimension calculation method for implementing the same.SOLUTION: The elevation angle of sight line for watching the image of a television screen formed by a reflector device can be set to less than 90°, by locating a reflector 1 above a reflector 2. Furthermore, a dimension calculation method for optimizing the dimensions of the reflector device and the elevation angle of sight line in correspondence with the size of the television or the change in position thereof is established. When using a reflector device configured by using that method, a television viewer can watch the image of a television screen in a comfortable posture with natural sight line.

Description

The present invention relates to viewing of a television using a device in which two planar reflecting mirrors are combined (hereinafter referred to as a reflecting mirror device ).

Conventionally, people who watch TV screens on their backs (hereinafter referred to as TV viewers ) while lying on the floor, bed, etc. (hereinafter referred to as the supine surface ) have been cramped, such as lifting their faces when watching TV screens in their feet. I was taking a posture.

JP 2002-10175A (P2002-10175A) (H19.09.25 deemed withdrawal)

However, according to the above technique, the elevation angle (* 1) of the line of sight of the TV screen image (hereinafter referred to as TV screen image ) formed by the reflecting mirror device exceeds 90 °, and the TV viewer can use the upper eye. You will see the image on the TV screen.
Further, there is no disclosure about a method for calculating the dimensions of each part of the reflecting mirror device (hereinafter, a dimension calculating method ).
SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a reflecting mirror device that forms an image of a television screen at an optimal position where the elevation angle of the line of sight is around 70 °, and to provide a dimension calculation method for realizing this. And
(* 1) Elevation angle refers to the angle of the line of sight of a TV viewer (hereinafter referred to as line of sight ) viewing the TV screen image. The foot direction parallel to the supine surface is 0 ° and the upper direction perpendicular to the supine surface is 90 °. And

In order to solve the above problems, the first invention is a reflecting mirror device characterized in that the reflecting mirror (1) (* 2) is positioned above the reflecting mirror (2) (* 3).
Further, the second invention establishes a dimension calculation method for optimizing the dimension of the reflector device and the elevation angle of the line of sight in response to changes in the size of the television and the position of the television. It is a mirror device.
(* 2) Reflecting mirror ( 1 ) refers to a reflecting mirror that reflects light emitted from a television screen toward reflecting mirror (2).
(* 3) The reflecting mirror ( 2 ) refers to a reflecting mirror that reflects the light that has come out of the TV screen and reflected by the reflecting mirror (1) toward the eyes of the TV viewer (hereinafter referred to as viewpoint ).

According to the first invention, an image of a television screen can be formed at a position where the elevation angle of the line of sight is less than 90 ° in a state where the television is positioned in the foot direction of the television viewer.
Furthermore, according to the second invention, the dimensions of the reflector device and the elevation angle of the line of sight can be optimized in accordance with changes in the size of the television and the position of the television.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view showing an embodiment of the present invention, in which a “sign representing an angle” used in a calculation formula ( * 4) is added. (* 4) The formula is a formula for calculating the dimensions of each part of the reflector device. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view showing an embodiment of the present invention, in which a “sign indicating a length” used in a calculation formula is added. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view showing an embodiment of the present invention, in which a “sign indicating a length” used in a calculation formula is added. It is the side view and perspective view which show one Embodiment of this invention, and attaches | subjects the "code | symbol showing the dimension of a reflective mirror apparatus" used for a calculation formula in the figure.

One embodiment of the present invention is shown in FIGS.
The light emitted from the television screen is reflected by the reflecting mirror (1) and the reflecting mirror (2) and reaches the viewpoint.
The television viewer can see the image of the television screen formed at the position that has passed through the reflecting mirror (2).

The items related to the calculation formula and dimension calculation method are shown below.
“Conditions for determining the formula” (0010)
“Symbols used in formulas” (0011)
"Determination of the calculation formula" (0012)
“Dimension Calculation Method Using All Calculation Formulas (General Calculation Procedure)” (0013)
"Dimension calculation method using some formulas (simple calculation procedure)" (0014)

"Conditions for determining the formula"
(10a) Vertical dimension of reflecting mirror When an image on a television screen is viewed with the viewpoint fixed, the vertical dimension is set to 2.0 times or more the minimum dimension at which the upper and lower ends of the image can be seen.
(10b) Horizontal dimension of reflecting mirror When viewing an image on a television screen with one eye in a state where the viewpoint is fixed, the horizontal dimension of the reflecting mirror is set to 1.5 times or more of the minimum dimension at which the left and right ends of the image can be seen.
Furthermore, 8 cm is added to the horizontal dimension of the reflector in consideration of the increase in the horizontal width due to the distance between the eyes of the TV viewer.
(10c) Range of angle of a straight line from “center of reflector (1)” to “center of TV screen” (see FIG. 1)
The range is 0 ° to 10 °.
(10d) The posture of the supine surface The supine surface is horizontal. (* 5)
(* 5) “Horizontal” is set to be convenient for determining the calculation formula and does not prescribe the posture when using the reflector device.
(10e) Angle of “mirror surface of reflecting mirror (2)” It is set to 90 ° with respect to the supine surface. (* 6)
(* 6) “90 °” is set to be convenient for determining the calculation formula, and does not prescribe the angle when using the reflector device.

"Symbols and symbols used in formulas"
According to the paragraph [Explanation of symbols] described later.

"Determining the formula"
(12a) J
J = G + N * sin α + M * sin α
= G + (M + N) * sinα .......................................... (1)
(12b) γ
tanγ = [(F + H / 2) −J] / L
Therefore, γ = tan ⁻¹ [(F + H / 2−J) / L] (2)
(12c) θ
Since the normal of the mirror surface of the reflecting mirror (1) is a direction obtained by dividing (β + γ) into two equal parts,
δ = (β + γ) / 2−γ = (β−γ) / 2
On the other hand, the mirror surface of the reflecting mirror (2) is vertical,
β = α
Therefore, δ = (α−γ) / 2
Since the angle θ is equal to the angle between the surface normal of the reflecting mirror (1) and the surface normal of the reflecting mirror (2),
θ = δ = (α−γ) / 2 ………………………………………………………… (3)
(12d) Hm1
The length from “center of TV screen” to “viewpoint”
L / cos γ + M + N≈L + M + N
The length from “Reflector (1)” to “Viewpoint” is
M + N
Therefore, the decrease rate of Hm1 with length is
(M + N) / (L + M + N) (A)
Since the incident angle is (β + γ) / 2, while β = α,
Incident angle is (α + γ) / 2
Therefore, the increase rate of Hm1 with the incident angle is
1 / cos [(α + γ) / 2] ……………………………………………………………… (I)
From formula (A) and formula (I),
Hm1 = 2.0 * H * [(M + N) / (L + M + N)] / cos [(α + γ) / 2] (4)
(12e) Wm1
The decrease rate of Wm1 due to the length is the same as Hm1,
(M + N) / (L + M + N)
Therefore,
Wm1 = 1.5 * W * [(M + N) / (L + M + N)] + 8 cm (5)
(12f) Hm2
The length from “center of TV screen” to “viewpoint”
L / cos γ + M + N≈L + M + N
The length from “Reflector (2)” to “Viewpoint” is
N
Therefore, the decrease rate of Hm2 with length is
N / (L + M + N) .......................................... (c)
Since the incident angle is α, the increase rate of Hm2 by the incident angle is
1 / cosα ………………………………………… (D)
From formula (c) and formula (d),
Hm2 = 2.0 * H * [N / (L + M + N)] / cosα (6)
(12g) Wm2
The decrease rate of Wm2 due to length is the same as Hm2,
N / (L + M + N)
Therefore,
Wm2 = 1.5 * W * [N / (L + M + N)] + 8 cm …………………………………… 7
(12h) M
Focusing on the length in the vertical direction,
M * sin α = (Hm1 * cos θ + Hm2) / 2
Therefore, M = (Hm1 * cosθ + Hm2) / (2 * sinα) (8)
On the other hand, focusing on the lateral length,
M * cos α = Y + Hm1 * sin θ / 2
Therefore, M = (Y + Hm1 * sin θ / 2) / cos α (9)
(12i) Y
From Formula (8) = Formula (9) (Hm1 * cos θ + Hm2) / (2 * sin α) = (Y + Hm1 * sin θ / 2) / cos α
Therefore, Y = (Hm1 * cosθ + Hm2) * (cosα / 2sinα) − (Hm1 * sinθ / 2)
= [(Hm1 * cos θ + Hm2) / tan α−Hm1 * sin θ] / 2
‥‥‥‥‥‥‥ ▲ 10 ▼
(12j) Z
Z = Hm1 * cosθ ………………………………………… 11

"Dimension calculation method using all calculation formulas (general calculation procedure)"
(13a) H, W, L, F, G, N, and α are set.
(13b) Temporarily set M.
(13c) J, γ, θ, Hm1, Wm1, Hm2, and Wm2 are calculated.
J = G + (M + N) * sinα (1)
γ = tan ⁻¹ [(F + H / 2−J) / L] (2)
θ = (α−γ) / 2 ……………………………………………… (3)
Hm1 = 2.0 * H * [(M + N) / (L + M + N)] / cos [(α + γ) / 2]
………………………………………………………… (4)
Wm1 = 1.5 * W * [(M + N) / (L + M + N)] + 8 cm
‥‥‥‥‥‥‥‥ ▲ 5 ▼
Hm2 = 2.0 * H * [N / (L + M + N)] / cosα
………………………………………………………… (6)
Wm2 = 1.5 * W * [N / (L + M + N)] + 8 cm …………………………………… 7
(13d) Hm1, Wm1, Hm2, and Wm2 are determined with reference to the calculated values of Hm1, Wm1, Hm2, and Wm2.
(13e) Y and Z are calculated.
Y = [(Hm1 * cos θ + Hm2) / tan α−Hm1 * sin θ] / 2
‥‥‥‥‥‥‥ ▲ 10 ▼
Z = Hm1 * cosθ ………………………………………… 11
(13f) M is calculated, compared with the temporarily set value, and when the value is different, the above (22-2) is repeated.
M = (Hm1 * cos θ + Hm2) / (2 * sin α) ………………………………………… (8)
M = (Y + Hm1 * sin θ / 2) / cos α (9)

"Dimension calculation method using some formulas (simple calculation procedure)"
(14a) α and γ are set.
(14b) θ is calculated.
θ = (α−γ) / 2 ……………………………………………… (3)
(14c) Hm1, Wm1, Hm2, and Wm2 are set. (* 7)
(* 7)
In the above-described “general calculation procedure”, H, W, L, G, N, and M are set and used to calculate Hm1, Wm1, Hm2, and Wm2.
In the “simple calculation procedure”, Hm1, Wm1, Hm2, and Wm2 are set directly without setting H, W, L, G, N, and M.
(14d) Calculate Y and Z.
Y = [(Hm1 * cos θ + Hm2) / tan α−Hm1 * sin θ] / 2
‥‥‥‥‥‥‥ ▲ 10 ▼
Z = Hm1 * cosθ ………………………………………… 11

"Effect of the embodiment"
According to this embodiment, the television screen image can be formed at an optimum position where the elevation angle of the line of sight is around 70 ° with the television positioned in the foot direction of the television viewer. The TV screen image can be viewed with a comfortable posture and a natural line of sight, especially for those who feel painful in bending the cervical spine or who have a disability when watching TV. It becomes.

Symbol for addition / subtraction / multiplication / division +: Addition-: Subtraction *: Multiplication /: Division

Symbol representing angle (see FIG. 1)
The foot direction parallel to the supine surface is the angle reference (0 °). (The direction indicated by the arrow in FIG. 1)
α: Angle of straight line from “viewpoint” to “center of TV screen image” (elevation angle of line of sight)
β: Angle of a straight line from “center of reflector 1” to “center of reflector 2” (* 8)
γ: Angle of the straight line from “center of reflector (1)” to “center of TV screen” (* 8)
δ: Angle of surface normal of reflector (1) θ: Angle formed by “mirror surface of reflector (1)” and “mirror surface of reflector (2)” (* 8) Viewpoint and TV screen (or TV screen) Strictly speaking, the center of the TV screen (or the image of the TV screen) does not pass through the center of the reflector because the plane of the reflector is not perpendicular to the line connecting the centers of Since this is slight, this deviation is ignored.

Symbol for length (see FIGS. 2 and 3)
F: Height from the “back surface” to the “lower end of the TV screen” G: Height from the “back surface” to the “view point” J: Height from the “back surface” to the “center of the reflector 1” L: Horizontal length from “center of TV screen” to “center of reflector 1” M: length from “center of reflector 1” to “center of reflector 2” N: Length from “center of reflector (2)” to “viewpoint” H: Vertical dimension of TV screen W: Horizontal dimension of TV screen

Reference numerals representing dimensions of the reflector device (see FIG. 4)
Hm1: Vertical dimension of reflecting mirror (1) Wm1: Horizontal dimension of reflecting mirror (1) Hm2: Vertical dimension of reflecting mirror (2) Wm2: Horizontal dimension of reflecting mirror (2) Y: Top of reflecting mirror (1) ”To“ Top of Reflector Mirror 2 ”Z: Height from“ Top of Reflector Mirror 1 ”to“ Top of Reflector Mirror 2 ”

The items related to the calculation formula and dimension calculation method are shown below.
“Conditions for determining the formula” (0010)
“Symbols and Signs Used in Calculation Formulas” (0011)
"Determination of the calculation formula" (0012)
“Dimension Calculation Method Using All Calculation Formulas (General Calculation Procedure)” (0013)
"Dimension calculation method using some formulas (simple calculation procedure)" (0014)

"Dimension calculation method using all calculation formulas (general calculation procedure)"
(13a) H, W, L, F, G, N, and α are set.
(13b) Temporarily set M.
(13c) J, γ, θ, Hm1, Wm1, Hm2, and Wm2 are calculated.
J = G + (M + N) * sin α
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 1 ▼
γ = tan ⁻¹ [(F + H / 2−J) / L]
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 2 ▼
θ = (α−γ) / 2
……………… ▲ 3 ▼
Hm1 = 2.0 * H * [(M + N) / (L + M + N)] / cos [(α + γ) / 2]
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 4 ▼
Wm1 = 1.5 * W * [(M + N) / (L + M + N)] + 8 cm
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 5 ▼
Hm2 = 2.0 * H * [N / (L + M + N)] / cosα
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 6 ▼
Wm2 = 1.5 * W * [N / (L + M + N)] + 8 cm
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 7 ▼
(13d) Hm1, Wm1, Hm2, and Wm2 are determined with reference to the calculated values of Hm1, Wm1, Hm2, and Wm2.
(13e) Y and Z are calculated.
Y = [(Hm1 * cos θ + Hm2) / tan α−Hm1 * sin θ] / 2
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 10 ▼
Z = Hm1 * cosθ
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 11 ▼
(13f) M is calculated, compared with the temporarily set value, and if the value is different, the above ( 13b ) is repeated.
M = (Hm1 * cos θ + Hm2) / (2 * sin α)
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 8 ▼
M = (Y + Hm1 * sin θ / 2) / cos α
・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ▲ 9 ▼

"Effect of the embodiment"
According to this embodiment, the television screen image can be formed at an optimum position where the elevation angle of the line of sight is around 70 ° with the television positioned in the foot direction of the television viewer. The TV screen image can be viewed with a comfortable posture and a natural line of sight, especially for those who feel painful in bending the cervical spine or who have a disability when watching TV. It becomes.
In addition, when watching 3D television using 3D glasses, according to this embodiment, a correct 3D image can be obtained. This is because the “line connecting the center points of both eyes of the 3D glasses” and the “horizontal line of the television screen (or an image of the television screen)” are in a parallel state.

Claims (2)

Reflector device combining two reflectors (* 2) (repost) reflector , characterized in that reflector ( 1 ) (* 2) is positioned above reflector (2) (* 3) (1) refers to a reflecting mirror that reflects light emitted from a television screen toward a reflecting mirror (2).
(* 3) (Repost) Reflector ( 2 ) refers to a reflector that reflects light reflected from the reflector (1) out of the TV screen toward the eyes of the TV viewer. Establishing a method (* 9) for calculating an optimum dimension for the reflector apparatus described above (* 9) A technique for calculating an optimum dimension is a reflector apparatus corresponding to changes in the size of the television and the position of the television. This is a dimension calculation method for optimizing the dimensions and the elevation angle of the line of sight.

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