JPH10227637A - Electronic equipment with electronic type inclinometer and altimeter - Google Patents
Electronic equipment with electronic type inclinometer and altimeterInfo
- Publication number
- JPH10227637A JPH10227637A JP9033477A JP3347797A JPH10227637A JP H10227637 A JPH10227637 A JP H10227637A JP 9033477 A JP9033477 A JP 9033477A JP 3347797 A JP3347797 A JP 3347797A JP H10227637 A JPH10227637 A JP H10227637A
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- Prior art keywords
- measurement
- electronic
- altitude
- data
- distance
- Prior art date
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Abstract
Description
【0001】[0001]
【発明の属する技術分野】本発明は、電子式傾斜計と電
子式高度計を備え、傾斜角(伏角)の計測と高度の計測
のデータにより、計測点と計測対象物間の距離を算出す
る機能を有する電子機器に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention comprises an electronic inclinometer and an electronic altimeter, and calculates a distance between a measurement point and an object to be measured on the basis of data of measurement of inclination (elevation angle) and altitude. And an electronic device having the same.
【0002】[0002]
【従来の技術】近年、一般の人々もパラグライダーや気
球に乗って有視界飛行を楽しむ競技が流行するようにな
ってきた。このような飛行においては飛行を始めたとこ
ろから一定の目標地までをいかに速く飛ぶかを競うのが
一般的である。2. Description of the Related Art In recent years, sports in which ordinary people enjoy visual flight on paragliders and balloons have become popular. In such a flight, it is common to compete for how fast to fly from the start of the flight to a certain destination.
【0003】以下、気球飛行を例に説明する。まず、図
5は気球飛行に使用するスタート地点とゴール地点を示
した地図である。図5に示すように、気球飛行は有視界
飛行で、地図50に示したスタート地点51をスタート
し、地図50と磁気コンパスを使い、以下で説明する方
法により気球現在地点O54(計測点)を確認しながら
飛行し、スタート地点51とゴール地点52を直線で結
んだ最短飛行コース53にできるだけ沿って短時間でゴ
ール地点52に到達しようとするスポーツである。[0003] Hereinafter, a balloon flight will be described as an example. First, FIG. 5 is a map showing a start point and a goal point used for balloon flight. As shown in FIG. 5, the balloon flight is a visual flight, starting at the start point 51 shown in the map 50, and using the map 50 and the magnetic compass to determine the balloon current point O54 (measurement point) by the method described below. This is a sport in which the user flies while checking and tries to reach the goal point 52 in a short time as possible along the shortest flight course 53 connecting the start point 51 and the goal point 52 with a straight line.
【0004】図6は地図と磁気コンパスによって計測さ
れた方角を使って気球現在地点を求める従来の方法を説
明する図である。まず、地図50上の計測対象物A5
5、B56の気球現在地点O54からの磁気コンパス6
0の磁針60aとなすそれぞれの方角、角度A65、角
度B66を磁気コンパス60を使って求め、計測対象物
A55、B56を通り、磁針60aと平行な基準線A6
1,B62から角度A65、B66の線分A63、B6
4を分度器を使って引くと、それぞれの線分の交点が求
める気球現在地点O54となる。FIG. 6 is a view for explaining a conventional method for obtaining the current position of a balloon using a direction measured by a map and a magnetic compass. First, the measurement object A5 on the map 50
5. Magnetic compass 6 from the balloon current position O54 of B56
The direction, angle A65, and angle B66 of each of the 0 magnetic needles 60a are obtained using the magnetic compass 60, and the reference line A6 passes through the measurement objects A55, B56 and is parallel to the magnetic needles 60a.
Line segments A63, B6 of angles A65, B66 from 1, B62
When 4 is drawn using a protractor, the intersection of each line segment becomes the current balloon position O54 to be obtained.
【0005】図8は従来の気球現在地点を求める方法の
原理の説明図である。図8を使ってこの原理を説明す
る。O、A、Bはそれぞれ図6に示した気球現在位置O
54、計測対象物A55、B56である。また、A
A’、BB’はそれぞれ磁針60a方向線分OO’に平
行なそれぞれA、Bを通る線分である。OO’とA
A’、OO’とBB’が平行なことより、∠O’OA=
∠OAA’=角度A、∠O’OB=∠OBB’=角度B
となり、線分AB、∠OAB=∠A’AB−角度A、∠
OBA=∠B’BA−角度Bより三角形OABが決まる
ので、点Oの位置を求めることが出来る。FIG. 8 is an explanatory view of the principle of a conventional method for obtaining the current position of a balloon. This principle will be described with reference to FIG. O, A, and B are the current balloon positions O shown in FIG.
54, measurement objects A55 and B56. Also, A
A ′ and BB ′ are line segments that respectively pass through A and B parallel to the line segment OO ′ in the direction of the magnetic needle 60a. OO 'and A
Since A ′, OO ′ and BB ′ are parallel, ∠O′OA =
∠OAA '= angle A, ∠O'OB = ∠OBB' = angle B
And the line segment AB, ∠OAB = ∠A′AB−angle A, ∠
Since the triangle OAB is determined from OBA = ∠B′BA−the angle B, the position of the point O can be obtained.
【0006】[0006]
【発明が解決しようとする課題】しかしながら、従来の
磁気コンパスを使って計測点を求める方法には精度的に
問題がある。つまり、計測対象物A、Bの計測点からの
それぞれの方角を磁気コンパスを使って求めるのである
が、肉眼で磁気コンパスの方位目盛りを計測対象物に合
わせるために、方位目盛りと計測対象物との合わせ誤差
が生じ易く、前記方角が精度よくでないので、計測点も
精度よく算出できないという問題があった。However, there is a problem in accuracy in the conventional method of obtaining a measurement point using a magnetic compass. In other words, the respective directions from the measurement points of the measurement objects A and B are obtained using the magnetic compass, but in order to match the azimuth scale of the magnetic compass with the measurement object with the naked eye, the azimuth scale and the measurement object are used. There is a problem that the measurement point cannot be calculated with high accuracy because the alignment error easily occurs and the direction is not accurate.
【0007】また、前記方角が求まっても、分度器によ
り、各計測対象物A55、B56から、基準線A61、
B62に対して角度A65、B66となる線分A63、
B64を引く面倒さがあった。Even if the direction is determined, a protractor separates the reference lines A61, A61 from the respective measurement objects A55, B56.
A line segment A63 at angles A65 and B66 with respect to B62,
There was trouble to pull B64.
【0008】本発明は、上記課題に鑑みてなされたもの
で、地図上で計測点を求めるために必要な計測点と計測
対象物間の距離を容易に精度よく計測できる電子式傾斜
計高度計付電子機器を提供することを目的とする。The present invention has been made in view of the above-mentioned problems, and has an electronic inclinometer that can easily and accurately measure a distance between a measurement point and a measurement object necessary for obtaining a measurement point on a map. An object is to provide an electronic device.
【0009】[0009]
【課題を解決するための手段】電子式傾斜計と電子式高
度計を有する電子機器において、該電子機器は、前記電
子式傾斜計による傾斜角の計測機能と前記電子式高度計
による高度の計測機能とを独立して有し、前記電子機器
に備えた外部入力手段により該電子機器に入力された高
度を持つ計測対象物と計測点との傾斜角と、前記電子式
高度計により計測点の高度とを計測し、計測対象物の傾
斜角の計測データと計測対象物の高度差の計測データか
ら計測対象物と計測点間の距離を算出し、該距離を前記
電子機器に設けた表示体に表示する機能を有することを
特徴としている。In an electronic device having an electronic inclinometer and an electronic altimeter, the electronic device has a function of measuring an inclination angle by the electronic inclinometer and a function of measuring an altitude by the electronic altimeter. Independently, the inclination angle between the measurement object and the measurement point having the altitude inputted to the electronic device by the external input means provided in the electronic device, and the altitude of the measurement point by the electronic altimeter. Measure, calculate the distance between the measurement object and the measurement point from the measurement data of the inclination angle of the measurement object and the measurement data of the altitude difference of the measurement object, and display the distance on a display provided in the electronic device. It has a function.
【0010】前記電子式傾斜計高度計付電子機器は、計
測点から計測対象物までの傾斜角を計測するために使用
する、計測対象物を拡大して見れる照準器を有すること
を特徴とする。The electronic inclinometer altimeter-equipped electronic device is characterized in that it has a sight used to measure an inclination angle from a measurement point to an object to be measured so that the object to be measured can be viewed in an enlarged manner.
【0011】[0011]
【発明の実施の形態】以下本発明の実施の形態について
図面に基づいて詳述する。初めに本発明の計測対象物の
傾斜角の計測データと計測点の高度の計測データから計
測対象物と計測点間の距離を算出し、この距離を液晶表
示する、回路ブロック図を図1を用いて説明する。な
お、以下の説明において、電子式傾斜計による計測対象
物の傾斜角の計測において、計測対象物の高度が気球現
在地点よりも一般には低い場合が対象となるので、傾斜
角を伏角とも言う。Embodiments of the present invention will be described below in detail with reference to the drawings. First, the distance between the measurement object and the measurement point is calculated from the measurement data of the inclination angle of the measurement object of the present invention and the measurement data of the altitude of the measurement point, and this distance is displayed on a liquid crystal. It will be described using FIG. In the following description, in the measurement of the inclination angle of the measurement object by the electronic inclinometer, the case where the altitude of the measurement object is generally lower than the current position of the balloon is an object, and therefore, the inclination angle is also referred to as the inclination.
【0012】前記回路ブロックはマイコン1と、該マイ
コン1に接続する液晶表示体2、電子式傾斜計3と電子
式高度計4と外部入力手段9から構成される。該マイコ
ン1は、前記電子式傾斜計3に接続し、該電子式傾斜計
3を駆動し且つ該電子式傾斜計3からの出力信号を入力
する傾斜角計測手段5と、前記電子式高度計4に接続
し、該電子式高度計4を駆動し且つ該電子式高度計4か
らの出力信号を入力する高度計測手段6を備えている。The circuit block comprises a microcomputer 1, a liquid crystal display 2 connected to the microcomputer 1, an electronic inclinometer 3, an electronic altimeter 4, and external input means 9. The microcomputer 1 is connected to the electronic inclinometer 3, and drives the electronic inclinometer 3 and inputs an output signal from the electronic inclinometer 3. And an altitude measuring means 6 for driving the electronic altimeter 4 and inputting an output signal from the electronic altimeter 4.
【0013】更にマイコン1は、前記傾斜角計測手段5
と前記高度計測手段6に接続し、傾斜角計測手段5と高
度計測手段6からの計測対象物の傾斜角計測データと計
測点の高度計測データから計測対象物と計測点間の距離
データを算出するメモリ付演算手段7、また該演算手段
7に接続し、該距離データを液晶表示体2に表示するた
めに液晶表示体2を駆動する液晶表示駆動手段8から構
成されている。もちろん、前記マイコン1は、前記電子
式傾斜計3と前記電子式高度計4を独立に動作させ、計
測対象物の傾斜角計測データと計測点の高度計測データ
を液晶表示体2に表示する機能を有する。The microcomputer 1 further includes the inclination angle measuring means 5.
Is connected to the altitude measuring means 6, and distance data between the measuring object and the measuring point is calculated from the inclination angle measuring data of the measuring object from the inclination measuring means 5 and the altitude measuring means 6 and the altitude measuring data of the measuring point. And a liquid crystal display driving means 8 connected to the calculating means 7 and driving the liquid crystal display 2 to display the distance data on the liquid crystal display 2. Of course, the microcomputer 1 has a function of operating the electronic inclinometer 3 and the electronic altimeter 4 independently, and displaying the inclination angle measurement data of the measurement object and the altitude measurement data of the measurement point on the liquid crystal display 2. Have.
【0014】図5は気球飛行地図である。該スタート地
点51からゴール地点52までを直線で結んだ最短飛行
コース53にできるだけ沿って短時間に飛行するため
に、気球現在地点O54を逐次地図50上で確認する必
要がある。以下本発明の気球現在地点O54の確認方法
を説明する。FIG. 5 is a balloon flight map. In order to fly as quickly as possible along the shortest flight course 53 connecting the start point 51 and the goal point 52 with a straight line, it is necessary to sequentially check the current balloon position O54 on the map 50. Hereinafter, a method for confirming the current balloon position O54 according to the present invention will be described.
【0015】図7は本発明の気球現在地点を求める方法
の原理の説明図である。図7を使って、この原理を説明
する。O、A、Bはそれぞれ図5に示した気球現在位置
O54、計測対象物A55、B56である。線分AB、
AO=lA、BO=lBより三角形OABが決まるの
で、点Oの位置が求まる。FIG. 7 is an explanatory diagram of the principle of the method for obtaining the current balloon position according to the present invention. This principle will be described with reference to FIG. O, A, and B are the current balloon position O54 and measurement objects A55 and B56 shown in FIG. 5, respectively. Line segment AB,
Since the triangle OAB is determined from AO = IA and BO = IB, the position of the point O is determined.
【0016】次に、図3を使って計測対象物の伏角の計
測方法を説明する。図3は計測対象物の傾斜角の計測の
説明図である。図3(a)に示すように、目24により
腕20につけられた電子式傾斜計高度計付腕時計21に
設けられた照準器22に計測対象物23を合わせて、計
測対象物23の地平線25に対する伏角θ26を計測す
る。該照準器22により計測対象物23を拡大して見ら
れるので、計測対象物23を図3(b)に示す照準器2
2の十字線27に精度よく合わせられ、計測対象物23
の地平線25に対する伏角θ26を精度よく計測でき
る。Next, a method of measuring the dip of the object to be measured will be described with reference to FIG. FIG. 3 is an explanatory diagram of the measurement of the inclination angle of the measurement object. As shown in FIG. 3A, the measurement target 23 is aligned with a sight 22 provided on an electronic inclinometer altimeter watch 21 attached to the arm 20 by the eye 24, and the measurement target 23 is positioned with respect to the horizon 25. The inclination angle θ26 is measured. Since the measurement target 23 can be viewed in an enlarged manner by the sight 22, the measurement target 23 is moved to the sight 2 shown in FIG.
2 is precisely aligned with the cross hair 27 of the second
Can be accurately measured with respect to the horizon 25.
【0017】ここで、図4を使って距離データの算出方
法を説明する。図4は気球現在地点と計測対象物間の距
離の算出を説明するための図である。図4により、計測
対象物40の地平線43に対する伏角θ44と本電子機
器に取り付けた電子式高度計より求める、気球41に乗
っている人の計測点42の高度hと地図から求めた計測
対象物40の高度h0との高度差(h−h0)から気球
現在地点と計測対象物間の距離lを次式により求める。 l=(h−h0)/tanθ .......(数1)Here, a method of calculating distance data will be described with reference to FIG. FIG. 4 is a diagram for explaining calculation of the distance between the current balloon position and the measurement target. According to FIG. 4, the inclination angle θ44 of the measurement object 40 with respect to the horizon 43 and the altitude h of the measurement point 42 of the person riding the balloon 41 obtained from the electronic altimeter attached to the present electronic device and the measurement object 40 obtained from the map From the altitude difference (h-h0) with the altitude h0, the distance 1 between the current balloon position and the measurement object is obtained by the following equation. l = (h−h0) / tan θ. . . . . . . (Equation 1)
【0018】以上の操作を基に図1及び図3〜図5、図
7を参照して図2の計測対象物と計測点間の距離を求め
るフローチャートにより、本願の位置計測の方法につい
て説明する。まず地図50上の計測対象物A55とB5
6と気球現在位置O54(計測点)間の距離を求める必
要がある。図2により計測対象物A55と計測点間の距
離を求める手順を説明する。The position measurement method of the present invention will be described with reference to FIGS. 1 and 3 to 5 and 7 based on the above-mentioned operations and the flowchart of FIG. 2 for obtaining the distance between the measurement object and the measurement point. . First, the measurement objects A55 and B5 on the map 50
It is necessary to find the distance between the balloon 6 and the current balloon position O54 (measurement point). The procedure for obtaining the distance between the measurement object A55 and the measurement point will be described with reference to FIG.
【0019】まず、外部入力手段9によりマイコン1へ
計測対象物の高度入力が必要であれば計測対象物の高度
の入力を行い、高度入力が必要でなければ0を入力する
(S1)。これにより計測対象物高度が演算手段7のメ
モリに記憶される(S2)。First, the altitude of the object to be measured is input to the microcomputer 1 by the external input means 9 when the altitude of the object is required, and 0 is input when the altitude is not required (S1). Thereby, the height of the measurement object is stored in the memory of the calculating means 7 (S2).
【0020】次に図3に示すように、電子式傾斜計3と
照準器22を用いて伏角θ26の計測(S3)を行うこ
とにより、伏角計測データが傾斜角計測手段5を介して
演算手段7のメモリに記憶される(S4)。Next, as shown in FIG. 3, by measuring the dip angle θ26 using the electronic inclinometer 3 and the sight 22 (S3), the dip angle measurement data is calculated via the tilt angle measuring means 5 by the arithmetic means. 7 (S4).
【0021】つぎは、電子式高度計4を動作させて計測
点の高度が自動計測され(S5)、高度計測データが高
度計測手段6を介して演算手段7のメモリに記憶される
(S6)。これによって演算手段7では、前記伏角計測
データと、該高度計測データと計測対象物高度データと
の高度差データから、距離データが算出され、メモリに
記憶される(S7)。Next, the altitude of the measurement point is automatically measured by operating the electronic altimeter 4 (S5), and the altitude measurement data is stored in the memory of the arithmetic means 7 via the altitude measuring means 6 (S6). As a result, the calculating means 7 calculates distance data from the dip angle measurement data and the altitude difference data between the altitude measurement data and the altitude data of the object to be measured, and stores the distance data in the memory (S7).
【0022】つぎに、前記演算手段7は前記液晶表示駆
動手段8に前記距離データを出力し、該液晶表示駆動手
段8は前記液晶表示体2に気球現在地点O54と計測対
象物A55間の前記距離lA57を表示する(S8)。Next, the calculating means 7 outputs the distance data to the liquid crystal display driving means 8, and the liquid crystal display driving means 8 supplies the liquid crystal display 2 with the distance between the current balloon position O54 and the measurement object A55. The distance IA 57 is displayed (S8).
【0023】ここで、通常、もう1つの計測対象物B5
6に対して同様に再度前記のステップ1〜8を行う必要
があるため、S9工程の再度測定において、YESを選
択し、S1〜S8の操作を行って、気球現在地点O54
と計測対象物B56間の距離lB58を求める。そして
S9工程の再度測定において、NOとなり、これによっ
て本計測を終了する。Here, usually, another measurement object B5
Since it is necessary to perform the above-mentioned steps 1 to 8 again in the same manner for S6, YES is selected in the measurement again in step S9, and the operations in S1 to S8 are performed to obtain the current balloon position O54.
And the distance IB58 between the object and the measurement object B56 is obtained. Then, in the measurement again in the step S9, the result is NO, and the main measurement is terminated.
【0024】上記の計測で、気球現在地点O54と、計
測対象物A55及びB56間の各々の距離lA57、l
B58が求まったので、計測点と計測対象物までの距離
から、計測点を求める方法の説明図である図5を用い
て、地図50上で気球現在地点O54を求める方法を説
明する。地図50上で計測対象物A55、B56を中心
にして半径がそれぞれlA57、lB58の円弧A57
a、B58aをコンパスで描きそれぞれの円弧A57
a、B58aの交点が気球現在地点(計測点)O54と
して求まる。In the above measurement, the distances lA57 and lA57 between the balloon current point O54 and the measurement objects A55 and B56, respectively.
Since B58 has been obtained, a method for obtaining the current balloon point O54 on the map 50 will be described with reference to FIG. 5 which is an explanatory diagram of a method for obtaining the measurement point from the distance between the measurement point and the measurement object. Arcs A57 having a radius of lA57 and lB58, respectively, around the measurement objects A55 and B56 on the map 50
a, B58a are drawn with a compass and each arc A57
The intersection of a and B58a is determined as the balloon current point (measurement point) O54.
【0025】以上の説明により、計測点と計測対象物A
55、B56までの距離lA57、lB58を簡単に精
度よく求められ、計測対象物A55、B56を中心に、
コンパスで円弧A57a、B58aを描き、それぞれの
円弧A57a、B58aの交点として気球現在地点O5
4(計測点)を容易に求められる。As described above, the measurement point and the measurement object A
The distances lA57 and lB58 to 55 and B56 can be easily and accurately obtained, and the distances AA and B56 are centered on the measurement objects A55 and B56.
The arcs A57a and B58a are drawn with a compass, and the intersection of the respective arcs A57a and B58a is used as the balloon current point O5.
4 (measurement point) can be easily obtained.
【0026】前記気球現在地点O54が求まると前記最
短飛行コース53からどれだけずれているかがわかり、
該最短飛行コース53に向かって軌道修正できる。この
ような操作を次の測定対象物であるA59、B60等々
にも同様に行うことにより、順次軌道修正をしながら、
最短のコースを最速の時間で飛行が可能となる。When the current balloon position O54 is determined, it is possible to determine how far the shortest flight course 53 has deviated from it.
The trajectory can be corrected toward the shortest flight course 53. By performing such an operation on the next object to be measured, such as A59, B60, etc., in the same manner, while sequentially correcting the trajectory,
You can fly on the shortest course in the fastest time.
【0027】[0027]
【発明の効果】以上の詳細な説明によって示されたよう
に、請求項1、2に記載の本発明によれば、地図上で容
易に精度よく気球現在地点(計測点)を求めることがで
きる。As described in the above detailed description, according to the first and second aspects of the present invention, the current balloon position (measurement point) can be easily and accurately obtained on a map. .
【図1】本発明の回路ブロック図である。FIG. 1 is a circuit block diagram of the present invention.
【図2】本発明の距離計測フローチャートである。FIG. 2 is a distance measurement flowchart of the present invention.
【図3】伏角測定方法の説明図である。FIG. 3 is an explanatory diagram of a dip angle measuring method.
【図4】距離算出の説明図である。FIG. 4 is an explanatory diagram of distance calculation.
【図5】気球飛行のための地図である。FIG. 5 is a map for a balloon flight.
【図6】従来の気球現在地点を求める方法の説明図であ
る。FIG. 6 is an explanatory diagram of a conventional method for obtaining a current balloon position.
【図7】本発明の気球現在地点を求める方法の原理の説
明図でる。FIG. 7 is an explanatory diagram of the principle of the method for obtaining the current balloon position according to the present invention.
【図8】従来の気球現在地点を求める方法の原理の説明
図である。FIG. 8 is an explanatory diagram of the principle of a conventional method for obtaining a current balloon position.
3 電子式傾斜計 4 電子式高度計 5 傾斜角計測手段 6 高度計測手段 7 演算手段 10 計測対象物高度入力 13 伏角計測データ記憶 15 高度計測データ記憶 16 距離データ算出記憶 17 距離表示 22 照準器 26 44 伏角θ 54 気球現在地点O 57 距離lA 58 距離lB 65 角度A 66 角度B Reference Signs List 3 electronic inclinometer 4 electronic altimeter 5 tilt angle measuring means 6 altitude measuring means 7 arithmetic means 10 measuring object altitude input 13 dip angle measurement data storage 15 altitude measurement data storage 16 distance data calculation storage 17 distance display 22 sight 26 44 Angle of depression θ 54 Current balloon position O 57 Distance 1A 58 Distance 1B 65 Angle A 66 Angle B
Claims (2)
子機器において、該電子機器は、前記電子式傾斜計によ
る傾斜角の計測機能と前記電子式高度計による高度の計
測機能とを独立して有し、前記電子機器に備えた外部入
力手段により該電子機器に入力された高度を持つ計測対
象物と計測点との傾斜角と、前記電子式高度計により計
測点の高度を計測し、計測対象物の傾斜角の計測データ
と計測対象物の高度差の計測データから計測対象物と計
測点間の距離を算出し、該距離を前記電子機器に設けた
表示体に表示する機能を有することを特徴とする電子式
傾斜計高度計付電子機器。1. An electronic device having an electronic inclinometer and an electronic altimeter, wherein the electronic device independently controls a tilt angle measuring function by the electronic inclinometer and an altitude measuring function by the electronic altimeter. Measuring the inclination angle between the measurement object and the measurement point having an altitude input to the electronic device by the external input means provided in the electronic device, and measuring the altitude of the measurement point by the electronic altimeter; It has a function of calculating the distance between the measurement object and the measurement point from the measurement data of the inclination angle of the object and the measurement data of the altitude difference between the measurement objects, and displaying the distance on a display provided in the electronic device. Electronic equipment with electronic inclinometer altimeter.
計測点から計測対象物までの傾斜角を計測するために使
用する、計測対象物を拡大して見れる照準器を有するこ
とを特徴とする請求項1に記載の電子式傾斜計高度計付
電子機器。2. The electronic device with an electronic inclinometer altimeter,
The electronic instrument with an electronic inclinometer altimeter according to claim 1, further comprising a sight used to measure an inclination angle from the measurement point to the measurement object, the observation object being magnified and viewed.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP9033477A JPH10227637A (en) | 1997-02-18 | 1997-02-18 | Electronic equipment with electronic type inclinometer and altimeter |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP9033477A JPH10227637A (en) | 1997-02-18 | 1997-02-18 | Electronic equipment with electronic type inclinometer and altimeter |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| JPH10227637A true JPH10227637A (en) | 1998-08-25 |
Family
ID=12387635
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP9033477A Pending JPH10227637A (en) | 1997-02-18 | 1997-02-18 | Electronic equipment with electronic type inclinometer and altimeter |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPH10227637A (en) |
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2002082017A1 (en) * | 2001-04-09 | 2002-10-17 | Korea Research Institute Of Standards And Science | Capacitive sensor for measuring of inclination |
| KR101398946B1 (en) * | 2013-06-25 | 2014-05-27 | 서울시립대학교 산학협력단 | Apparatus, method and recording medium for control of smart watch |
| CN104236519A (en) * | 2014-09-22 | 2014-12-24 | 浙江荣胜工具有限公司 | Three-dimensional angle measurement device |
| JP2019128299A (en) * | 2018-01-26 | 2019-08-01 | セイコーエプソン株式会社 | Electronic watch, and method for controlling electronic watch |
| JP2019128300A (en) * | 2018-01-26 | 2019-08-01 | セイコーエプソン株式会社 | Electronic watch, and method for controlling electronic watch |
-
1997
- 1997-02-18 JP JP9033477A patent/JPH10227637A/en active Pending
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2002082017A1 (en) * | 2001-04-09 | 2002-10-17 | Korea Research Institute Of Standards And Science | Capacitive sensor for measuring of inclination |
| KR101398946B1 (en) * | 2013-06-25 | 2014-05-27 | 서울시립대학교 산학협력단 | Apparatus, method and recording medium for control of smart watch |
| CN104236519A (en) * | 2014-09-22 | 2014-12-24 | 浙江荣胜工具有限公司 | Three-dimensional angle measurement device |
| JP2019128299A (en) * | 2018-01-26 | 2019-08-01 | セイコーエプソン株式会社 | Electronic watch, and method for controlling electronic watch |
| JP2019128300A (en) * | 2018-01-26 | 2019-08-01 | セイコーエプソン株式会社 | Electronic watch, and method for controlling electronic watch |
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