JPH06197870A - Method of measuring temperature of ear using ear type thermometer - Google Patents

Abstract

PURPOSE:To provide a method of measuring a temperature of an ear, which can shorten the measuring period with the use of an ear type thermometer. CONSTITUTION:With the repetitions of measurement of a temperature of the external auditory canal with the use of an ear type thermometer having a probe which has been inserted in the external auditory canal and from which infrared radiation is transmitted from the field of vision to be measured in the external auditory canal, the waiting for stabilization after measurement is carried out only if the output Vtp of an infrared detector at the time when a measurement initiating switch is depressed, is larger a threshold value Vtrg which has been previously set.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention repeatedly measures an ear temperature using an ear thermometer which measures the ear temperature of the ear canal by passing infrared radiation from a measurement field of the ear canal through a probe inserted in the ear canal. More specifically, the present invention relates to a method for shortening the measurement interval including waiting for a stable time until the input permission period is set after the measurement start switch is pressed or the measurement result is displayed. .

[0002]

2. Description of the Related Art Generally, ear thermometers that measure body temperature by inserting a probe into the ear canal usually have a conical hood at the tip.

In use, the hood formed at the tip of the probe is inserted into the ear canal, and infrared rays from the measurement field of view are passed through an entrance window and a waveguide provided in the ear thermometer to detect an infrared ray ( The temperature of the ear canal applied to the measurement visual field is measured by the output of the infrared detector. At this time, the measurement result is displayed on the LCD via the microcomputer after the AD conversion of the output. Further, as the probe, a type in which the hood is covered with a probe cover or a type in which the hood and the probe cover are integrated is often used.

Conventionally, in this kind of ear thermometer, after the probe is inserted, regardless of the magnitude of the output of the infrared detector at the time of starting the measurement when the measurement start switch is pressed, after the measurement, before the next measurement is performed. The stabilization wait time (also called the measurement prohibition time) is set to always wait for stabilization.

[0005]

Therefore, even if the output of the infrared detector at the time of measurement start when the measurement start switch is pressed after the probe is inserted is different between the previous measurement and the next measurement, Regardless, the measurement interval between both measurements remains unchanged. As is well known, when the ear thermometer is used, it is possible to accurately measure the ear temperature by displaying the ear temperature not only once but repeatedly. Therefore, at least from the user, for example, , If the previous measurement time (mainly proportional to the probe insertion time) is much shorter than the next measurement time (mainly proportional to the probe insertion time), the measurement interval between them can be shortened, or / And after inserting the probe,
There is a demand for an ear thermometer that can shorten the measurement interval even when the output of the infrared detector when the measurement start switch is pressed is not constant but variable above and below a predetermined value. Then, when the ear temperature is repeatedly measured, the ear temperature can be accurately measured while shortening the total measurement time.

The present invention has been made in view of the above problems, and an object thereof is to provide an ear temperature measuring method capable of shortening the measurement interval in an ear thermometer.

[0007]

In order to solve the above problems, an ear temperature measuring method using an ear thermometer according to the present invention uses infrared radiation emitted from the visual field of the ear canal via a probe inserted in the ear canal. When repeatedly measuring the ear temperature using an ear thermometer that measures the ear temperature of the external auditory meatus by passing it through, the output of the infrared detector at the time of pressing the measurement start switch after inserting the probe is preset. It consists of waiting for stabilization after measurement only when it is larger than the threshold value.

Further, according to the present invention, from another viewpoint that the upper and lower limits of the stabilization waiting time can be set, the probe insertion time is determined from the output of the infrared detector and the signal of the measurement start switch, and the stabilization waiting time is By calculating from the probe insertion time and the infrared detector output level, the output of the infrared detector at the time of pressing the measurement start switch and the probe insertion time, when greater than a preset threshold, It is possible to provide an ear temperature measuring method using an ear thermometer, which is configured such that the stabilization waiting time is lengthened and varied.

In any of these cases, the gist of the invention is
This means that the stabilization waiting time can be made variable, and in this respect, the measurement method of the present invention is clearly different from the conventional measurement method in which the stabilization waiting time is fixed for each measurement,
Therefore, the measuring method of the present invention has various advantages described below.

[0010]

[Operation] After the probe is inserted, when the measurement start switch is pressed and the output of the infrared detector is larger than the preset threshold value, the stabilization wait after the measurement is performed. After that, it is not always necessary to wait for stabilization until the next measurement, and the measurement interval between both measurements can be made variable. As a result, when the ear temperature is repeatedly measured, the ear temperature can be accurately measured while shortening the total measurement time. Also, the output of the infrared detector and the probe insertion time at the time of pressing the measurement start switch,
When it is larger than a preset threshold value, the stabilization waiting time can be made long and variable. In any of these cases, the stabilization waiting time which was conventionally unchanged (fixed) is made variable.

[0011]

An embodiment of an ear temperature measuring method using an ear thermometer according to the present invention will be described below with reference to the drawings. The ear temperature measurement method is to insert the probe into the ear thermometer that repeatedly measures the ear temperature of the ear canal by passing infrared radiation from the measurement field of the ear canal through the probe inserted into the ear canal. After that, the stabilization waiting after the measurement can be performed only when the output (output of the thermopile) V _tp of the infrared detector at the time of pressing the measurement start switch is larger than the preset threshold V _trg. .

The operation will be described below. In FIG. 1, the probe insertion time T _M is defined in the time zone from the probe insertion time to the probe insertion time. At this time, the ear thermometer can be measured by pressing the measurement start switch after inserting the probe. Further, in the present embodiment, the stabilization waiting time is defined as the period after the measurement start switch is pressed until the input permission period is set. Furthermore, in the ear thermometer of the present embodiment, the measurement result (measurement end) is displayed at the same time when the probe is inserted. However, the present invention may include displaying the measurement result (measurement end) before inserting the probe.

Furthermore, the relationship between the signal V _on of the measurement start switch after inserting the probe and the signal V _off of the measurement end switch at the time of inserting the probe is k × under the condition of V _on > V _trg.
When V _on > V _trg , V _off = k × V _on . This V
coefficient k of _on, whether the probe is pulled out of the ear, i.e., is for calculating a threshold value for judging the presence or absence of the probe挿出. In this embodiment, k≈
It is 0.7. Also, under the condition of V _on > V _trg , k × V
If not _on> V _trg, it is a V _off = V _trg.

On the other hand, under the condition that the signal V _on of the measurement start switch after inserting the probe is not V _on > V _trg , that is, the output V _on of the infrared detector at the time of pressing the measurement start switch is previously set. Below the set threshold value V _trg , the stabilization wait after the measurement can be made unnecessary, and after the measurement, it is not necessary to wait for the stabilization until the next measurement.
When repeatedly measuring the ear temperature, the ear temperature can be accurately measured while shortening the total measurement time.

In FIG. 2, first, in step 101,
The probe is inserted within the input permission period of the measurement start switch, and the measurement start switch is turned on under the condition of V _tp (thermopile output) = V _on (signal of the measurement start switch) (see step 102). At the time when the measurement is completed (when the probe is inserted), the ear temperature of the measurement result is immediately displayed on the ear thermometer (see step 103).

Therefore, in the present embodiment, as shown in step 104, only when the output V _tp of the thermopile at the time when the measurement start switch is pushed is larger than the preset threshold V _trg. The feature is to wait for stabilization after measurement. That is, in step 104, V _on >
When it is not V _trg , the measurement is completed, and the input permission period of the measurement start switch for re-measurement can be immediately entered (see step 105). This eliminates the need to wait for stabilization after measurement, and after measurement, there is no need to wait for stabilization before moving on to the next measurement. The temperature can be measured accurately.

On the other hand, in step 104, when V _on > V _trg (the probe is inserted in the ear), first,
As shown in step 106, k × V _on > V
Under the condition of _trg , a threshold value for determining whether the probe is pulled out of the ear is calculated. In this embodiment, V
_off (measurement end switch signal) = k × V _on , k =
It becomes 0.7 (see step 107).

If V _on > V _trg in step 104, then k × V as shown in step 106.
_{If not on} > V _trg , V _off at step 108
= V _trg . In this way, it is possible to determine whether or not the probe has been inserted, and V _tp > V _off (see step 109) _{until there is a} stabilization waiting time T _nr (step 110).
After the reference), the input permission period of the measurement start switch for remeasurement in step 105 can be entered.

Thus, in this embodiment, the stabilization waiting time T
_{Although nr} is fixed, under the condition that the signal V _on of the measurement start switch after probe insertion is not V _on > V _trg , that is, the output V _on of the infrared detector when the measurement start switch is pressed is: At a preset threshold value V _trg or less, there is no need to wait for stabilization after the measurement, so that the ear temperature can be accurately measured while shortening the total measurement time when repeatedly measuring the ear temperature.

In this embodiment, the stabilization waiting time is shown to be unnecessary under a specific condition.
As another example, under another specific condition, the upper limit of the stability waiting time is increased, and under other conditions, the lower limit of the stability waiting time is decreased, so that the optimum waiting time is set for each measurement. You may make it possible to set it to a thing.
In this way, the total measurement time can be shortened as compared with the conventional measurement method in which the stabilization waiting time is fixed for each measurement. That is, in this other embodiment, the probe insertion time T _M can be determined from the output V _tp of the infrared detector and the signal V _{on of the} measurement start switch, and the stabilization waiting time T _nr
The probe insertion time T _M and the infrared detector output level V
It can be calculated from _tp .

[0021]

As described above, according to the present invention, the stabilization waiting time can be made unnecessary under specific conditions,
It enables you to set the optimum one for each measurement, and as a result, the effect that you can measure the ear temperature accurately while shortening the total measurement time compared to the conventional measurement method in which the stabilization waiting time is fixed for each measurement is there.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing an embodiment of the present invention.

FIG. 2 is a flowchart in the above embodiment.

[Explanation of symbols]

V _tp ... output of infrared detector, V _on ... signal of measurement start switch, T _M ... probe insertion time, V _trg ... preset threshold value, T _nr ... stabilization wait time.

Claims (3)

[Claims] 1. After repeatedly inserting a probe into an ear thermometer, the ear temperature of the ear canal is measured by passing infrared radiation from a measurement field of the ear canal through a probe inserted into the ear canal. The ear using the ear thermometer consists of waiting for stabilization after measurement only when the output of the infrared detector at the time of pressing the measurement start switch is larger than a preset threshold value. How to measure temperature. 2. The probe insertion time for repeatedly measuring the ear temperature using an ear thermometer that measures the ear temperature of the ear canal by passing infrared radiation from the measurement field of the ear canal through a probe inserted in the ear canal. Is determined from the output of the infrared detector and the signal of the measurement start switch, and the stabilization waiting time is calculated from the probe insertion time and the infrared detector output level, so that the infrared detector at the time of pressing the measurement start switch And a probe insertion time are larger than a preset threshold value, the stability waiting time is lengthened to be varied, and the ear temperature measuring method using the ear thermometer is used. 3. The ear temperature measuring method using the ear thermometer according to claim 2, wherein the stabilization waiting time has an upper limit and a lower limit.