JPH1020047A - Atmospheric pressure tendency value computing method and atmospheric pressure tendency display device using it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an atmospheric pressure tendency computing method, by which a weather tendency can be recognized and predicted, and an atmospheric pressure tendency display device. SOLUTION: A signal from a pressure sensor 20 is transformed into a pressure value by means of an A/D converting circuit 18, and a differential from a pressure value before a certain time is computed by means of a computing circuit 11. These data are stored in a RAM 12. In the computing circuit 11, time weighting, in which coefficients are multiplied by each other according to a time order of the differential values stored in the RAM 12 as tendency values of a pressure, is also carried out. As these pressure changes and tendencies are updated in every time, data for a weather forecast with higher probability than a conventional one are provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for calculating a pressure tendency value having a pressure detection function for detecting pressure using a pressure sensor and a timekeeping function, and a pressure tendency display device using the same.

[0002]

2. Description of the Related Art Conventionally, a timepiece in which other functions are added to a timepiece for performing timekeeping measurement has been proposed and commercialized. Among them, a sensor in which a diaphragm and a resistor are formed on a silicon chip, that is, a so-called diffusion type semiconductor sensor, has been put to practical use, and a watch provided with a barometric pressure measurement function using the sensor has been realized. When it is applied to a watch, it is carried and moved.Compared with a product that is fixed and used like a wall-mounted barometer, it can be used when the user wants to know the atmospheric pressure in daily life. Is used as one of the data when predicting the weather by graphically displaying as a pressure change.

[0003]

However, based on the concept of the standard atmosphere, it is a well-known fact that the pressure changes when the altitude changes. Has a problem that it is not possible to recognize whether the atmospheric pressure has changed due to a change in atmospheric pressure or altitude due to a change in atmospheric pressure. Also, the graphic display of the difference from the previous atmospheric pressure value with respect to the time change only shows a small change in the atmospheric pressure, and is not enough to recognize a large atmospheric pressure change due to the weather cycle.
In addition, it is also difficult to provide a portable watch with a large display area for displaying the pressure difference for several days. Therefore, in the present invention, even if the user of the watch moves while carrying it in daily life and the altitude changes, the altitude change is automatically recognized, and the progress information and the current time at which the weather cycle can be determined are displayed. It is an object of the present invention to provide an atmospheric pressure trend value calculating method and an atmospheric pressure trend display device capable of recognizing and predicting a weather tendency with a probability.

[0004]

In order to solve the above-mentioned problems, the present invention provides a method for calculating a pressure tendency value using a plurality of pressure values measured in time series. The difference between the air pressure value at the predetermined time and the air pressure value measured immediately before is obtained, and the air pressure value is determined such that the difference value closer to the current time has a higher weight with respect to the obtained plurality of difference values. Weighting is performed according to the measured time, and a pressure tendency value is obtained using a plurality of weighted difference values.

Further, the atmospheric pressure trend display device of the present invention is characterized in that it comprises a display unit for converting the atmospheric pressure tendency value into an index and displaying a graphic representation of the atmospheric pressure tendency in accordance with the index.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to examples.

FIG. 1 is a block diagram of an electronic timepiece according to the present invention. Reference numeral 17 denotes an oscillation circuit for generating a frequency serving as a reference of a time signal of the timepiece. 16 is a frequency dividing circuit, 15 is a time counter, and 14 is a control circuit for switching graphic display. 13a is a liquid crystal driver for displaying the liquid crystal display element 13b. The liquid crystal driver 13a displays the time 26 and the atmospheric fluctuation graphic 24 of FIG. 2 on the liquid crystal. 20 is a pressure sensor. The pressure sensor 20 is an element that detects a pressure change of a gas or a fluid and deforms silicon, thereby changing a bridge resistance, thereby causing a balance shift and a voltage change. The pressure sensor 20 converts the amount of atmospheric pressure into an electric signal and inputs the electric signal to the amplifier circuit 19. An amplified signal from the amplifier circuit is converted into an analog-digital converter circuit (hereinafter referred to as an A / D converter circuit).
18 and is converted from an analog signal 10a to a digital signal 10b. The digital signal 10b is input to the arithmetic circuit 11, calculated as an atmospheric pressure value, and stored in the RAM 12.

FIG. 2 is an external view of a timepiece to which the barometric pressure measurement function of the present invention is added. Reference numeral 21 denotes a watch case, which is a display unit, which is a liquid crystal display device. Reference numeral 23 denotes three switches for instructing a scale value and scrolling, which will be described later, on the side portion on the 3 o'clock side. Numeral 24 indicates a graphic representation of the change in atmospheric pressure up to the present, with the horizontal axis representing elapsed time and the vertical axis representing changes in atmospheric pressure.
Reference numeral 25 denotes the scale of the horizontal axis currently displayed on the atmospheric pressure fluctuation graphic 24. Reference numeral 27 denotes a graphic display unit that indicates the tendency of atmospheric pressure. In the present embodiment, the tendency of the atmospheric pressure change is classified into stages, and when displayed in the center, it indicates that there is almost no atmospheric pressure change. The change in the atmospheric pressure after a short time is predicted by looking at the above-described graphic 24 of the atmospheric pressure fluctuation. 26 displays the current time.

First, a graphic display showing a change in the atmospheric pressure will be described.

Atmospheric pressure is measured every hour and every 30 minutes.
Atmospheric pressure difference data DP 30 minutes ago by the arithmetic circuit 21
(T) is calculated as follows and stored in the RAM 22.
The number of storages is 48 times. When the number of times exceeds 48 times, old data is deleted and the latest data is always stored for 48 times.

−2.0 <P (t) −P (t−0.5
h) <2.0 DP (t) = P (t) −P (t−0.5h) −2.0 ≧ P (t) −P (t−0.5h) or P (t) − When P (t−0.5h) ≧ 2.0 DP (t) = 0 where P (t): Pressure data at time t P (t−0.5): Pressure 30 minutes before time t Data DP (t): Atmospheric pressure difference data at time t, that is, DP (t) = 0 when a pressure fluctuation of 2.0 hPa or more occurs within 0.5 h. This is because, in general, a pressure fluctuation in the same place does not change by 2.0 hPa or more within 30 minutes unless a sudden weather pressure change occurs, and a fluctuation of 2.0 hPa or more is caused by the movement of the carrier. It is presumed that it is a barometric pressure fluctuation resulting from altitude change.
In addition, the user's life pattern is to act in a certain fixed manner, and it is extremely rare that the user always moves at a different altitude every 30 minutes.

The data to be displayed graphically is every 0:00
Atmospheric pressure difference data D every 6 hours at 6:00, 12:00 and 18:00
P (t) is a total sum of 48 SDP (t), which is obtained and stored. The storage number of SDP (t) is 41 times, that is, data every 6 hours is 10 days, and when it exceeds 41 times, old data is deleted and the latest data is always stored 41 times.
The value indicated by SDP (t) is a large change in atmospheric pressure for several days when the movement of the carrier is canceled.

FIG. 3 is an external view of a graphic for displaying the atmospheric pressure fluctuation according to the present invention. 32 graphic displays
The minimum unit of display is 1 dot, the horizontal axis is 21 dots, the time axis is, and the vertical axis is the value of SDP (t). Display as The right end of the display unit 24 is the starting point of the graphic and always displays the latest data, and the left end displays past data. In this embodiment, 2 in FIG.
By the switch 3a, the scale, which is a unit of time displayed in the entire display width, is switched from 2 days to 10 days, and the scale value 25 is displayed. As an example, on the 5-day scale, the horizontal axis represents one dot 6 hours, and when the SDP (t) is calculated at 0 o'clock, 6 o'clock, 12 o'clock, and 18 o'clock, the entire currently displayed graphic is shifted one dot to the left. And rewrite the display. When the scale is switched, the scale value / 20 is established for the time represented by one dot on the horizontal axis, and the corresponding data is displayed from SDP (t) in the RAM.

FIG. 4 is a diagram showing a scroll operation which is a movement on the time axis according to the present invention. In FIG. 4, the scale value of the display area 42 is displayed for 5 days. In order to view the recorded SDP (t) data 41 for 10 days, the display area 42 of the scale for 5 days is scrolled in units of one dot with respect to the time axis of the horizontal axis by operating the switches 23b and 23c in FIG. I do. The scroll limit is from the data 43 at 0 o'clock 10 days before the left end of the display area to the current data 44 at the right end of the display area 42. In the operation of this embodiment, scrolling is performed leftward by the switch 13b and rightward by the switch 13c.

Data graphically displayed as described above is processed by data for 48 times every 30 minutes. It has been conventionally known that the atmospheric pressure value fluctuates extremely with movement during normal life, and when only the pressure difference from the previous time is displayed as data, it is set to 0 to prevent so-called jumps that suddenly change the graph. However, according to the present invention, the data obtained by canceling a sudden change in data due to movement or the like is calculated as a pressure change value indicating a large change in the atmosphere. The probability increases. In general, the atmospheric pressure changes periodically in the time axis of about 3 to 5 days. By providing a graphic that can display the atmospheric pressure change for 2 to 10 days, the periodicity of the atmospheric pressure change is provided. This also allows the user to make a more predictive judgment on weather fluctuations. Further, by arbitrarily scrolling the time display window, it is possible to visually recognize the change in the atmosphere from 10 days ago, and to immediately grasp the current weather trend.

Next, a description will be given of the atmospheric pressure tendency value indicating the fluctuation of the atmospheric pressure having a time deviation.

The data of 24 times including the latest data is divided from the 48 times of the differential data DP (t) of the atmospheric pressure calculated by the arithmetic circuit at every hour and every 30 minutes and stored in the RAM 12, and a coefficient is assigned to each range. The coefficient is multiplied by all of the data within the set range and the sum is calculated. In the present embodiment, numerical values are weighted so that the data in the area close to the latest data is divided into four parts and has several times the data in the past area. This sum value is a value that largely indicates a recent atmospheric pressure fluctuation as the atmospheric pressure tendency index A.

In general, when observing a change in atmospheric pressure for several days, small swells appear at intervals of about 12 hours in a large atmospheric pressure fluctuation that periodically fluctuates on a time axis of about 3 to 5 days. Therefore, if the atmospheric pressure has been rising for about 12 hours up to the present, the atmospheric pressure tendency index A becomes a very large value. Also, if the atmospheric pressure that had risen from 12 hours ago began to fall from 6 hours ago, and if the current time had the same value as 12 hours ago, the simple sum would be close to 0, but this bias was present. According to the atmospheric pressure tendency calculation, a negative value is obtained, and it is clearly indicated by a numerical value that the atmospheric pressure tends to decrease in a range close to the current time.

FIG. 5 is an external view of a graphic showing the atmospheric pressure tendency according to the present invention. The pressure tendency is indicated by the value of the pressure tendency index A. The barometric pressure trend display section 27 is composed of marks 52 arranged vertically in five rows and displays one mark according to the value of A, and rewrites the display every hour and every 30 minutes. In the embodiment, the upper mark indicates that A is larger, that is, the air pressure tends to increase. For example, when 52a is lit, the wearer can determine that the atmospheric pressure has been rising several hours ago or has increased significantly and the weather is improving.

It has already been described that the display of the pressure difference graphic for several hours as in the prior art is not enough to recognize atmospheric fluctuations due to weather fluctuations. As an actual use example of the present invention, the barometric pressure fluctuation graphic that displays the past change in various forms recognizes the atmospheric fluctuation period, and the barometric pressure trend graphic knows the barometric pressure trend in the past, so that the barometric pressure change is stronger. You can predict how the current weather is likely to change while being aware of the situation.

[0021]

As described above, according to the present invention, with respect to data with an elapsed time, a pressure fluctuation value having a temporal bias with an emphasis on the latest data is calculated and indexed, and the index is calculated according to the index. By providing the graphic display unit, the present and future weather can be determined, and a highly reliable prediction can be performed. For example, the weather tendency can be recognized and predicted with a higher probability than before.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an internal circuit of an embodiment.

FIG. 2 is a diagram illustrating an appearance of an embodiment of the present invention.

FIG. 3 is an external view of a graphic for displaying atmospheric pressure fluctuation.

FIG. 4 is a diagram showing a scroll operation of a display area.

FIG. 5 is an external view of a graphic for displaying a pressure tendency.

[Explanation of symbols]

 Reference Signs List 11 arithmetic circuit 12 RAM 13a liquid crystal driver 13b liquid crystal display element 14 control circuit 15 time counter 16 frequency dividing circuit 17 oscillation circuit 18 A / D conversion circuit 19 amplification circuit 20 pressure sensor 21 watch case 22 display unit 23a, 23b, 23c switch 24 Atmospheric pressure fluctuation graphic display unit 25 Scale display unit 26 Time display unit 27 Atmospheric pressure trend graphic display unit

Claims (2)

[Claims] 1. A method for calculating a pressure tendency value using a plurality of pressure values measured in time series, wherein a difference between a pressure value at a predetermined time and a pressure value measured immediately before the predetermined time is obtained. For the obtained multiple difference values,
Atmospheric pressure characterized by performing weighting according to the time at which an atmospheric pressure value is measured so that a differential value close to the current time has a higher weight, and obtaining an atmospheric pressure trend value using a plurality of weighted differential values. Trend value calculation method. 2. The pressure tendency value according to claim 1 is indexed,
An air pressure tendency display device comprising a display unit for performing a graphic display indicating an air pressure tendency according to the index.