JPS62209684A - Bar code reader - Google Patents

Abstract

PURPOSE:To grasp a speed in accordance with the pitch of a voice that a measuring person outputs by providing a voice output means which is driven by a read clock signal from a clock bar part and outputs a frequency corresponding to the scan speed of a bar code plate. CONSTITUTION:In terms of a bar code reading part 5, a bar code film 1 is inserted to an insertion path with an inlet hole 17 and an outlet hole 18. The bar code film 1 is comprised by providing a bar code part 3 and an insertion direction mark 4 on the surface of a film base 2. The bar code part 3 consists of two tracks: a clock bar part 3a provided with bars at the same interval, and a data bar part 3b recording data. The bar code film 1 is provided, because a detection mark table to measure blood sugar stored in the circuit of a blood sugar meter 11 has to be calibrated every time a test paper is locked, and calibration data has to be inputted. A buzzer 19 is arranged in the vicinity of a measurement start switch 14 in a case 12, and outputs the voice of frequency corresponding to the moving of the bar code film 1.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention relates to a barcode reading device, particularly a barcode reading device for reading a code on a barcode board on which two tracks, a data bar section and a clock bar section, are formed. Regarding.

(Example) Conventional technology Conventionally, for example, in blood sugar needles, etc., in order to calibrate the calibration curve daple in one main unit in response to variations in test strips from lot to lot, one calibration data is input using a barcode film. There is something that I tried to do. In this blood sugar needle, the case body has an insertion path through which the barcode film passes, and a barcode reader consisting of a light emitting element and a light receiving element is installed in the middle of this insertion path, and the barcode film passes through the insertion path. The barcode data is then read by the barcode reader. Also.

The barcode of the barcode film used here is
It consisted only of data pars consisting of a combination of narrow and wide.

(c) Problems to be solved by the invention In the above-mentioned blood sugar needle barcode film, the barcode consists only of narrow and wide data bars, and the decoding principle also determines whether the bar width is short or long. Therefore, if the speed at which the barcode film is pulled through the insertion path is too fast, too slow, or uneven, reading errors may occur. For this reason, it is desirable to scan the barcode film at a predetermined constant speed, but with conventional blood glucose meters, it is unclear how fast the barcode film was pulled, or how fast it should be pulled. However, there was no choice but to rely on the intuitive feeling of the measurer.

In view of the above, an object of the present invention is to provide a barcode reading device that can accurately grasp the scanning speed of a barcode film to some extent.

B) Means and operation for solving the problem The barcode reading device of the present invention scans a barcode plate on which two tracks, a data bar part and a clock bar part, are formed relative to a barcode reading part. , the clock bar is synchronized to some read signal.

A device for reading a signal from a part of the data bar is characterized by an audio output means that is driven in response to a reading clock signal from the clock bar section and outputs audio at a frequency corresponding to the scanning speed of the bar code plate.

This barcode reader uses barcode (film)
When the board is moved relative to the barcode reader,
The puff code clock in the clock section of the bar code board is read, and in synchronization with this read output, the bar code data on a part of the data bar is read. Further, a sound corresponding to the frequency of the read clock signal of the clock bar section is outputted by the sound output means. If the scanning speed of the knob or barcode plate is high, a high frequency sound will be output, and conversely, if the scanning speed is low, a low frequency sound will be output. The measurer listens to the output audio and determines whether or not the speed is appropriate based on the pitch of the audio.

(e) Examples The present invention will be explained in more detail with reference to Examples below.

FIG. 1 is an external perspective view of the example blood glucose meter.

In the figure, a blood glucose meter 11 has a case 12 made of synthetic resin.
The measuring section, barcode reading section, etc. are housed inside, and case 1
A power switch 15, a measurement start switch 14, and a liquid crystal display 15 for displaying blood sugar levels and the like are provided on the top surface of the device 2. A measuring section cover 16 that covers the entire measuring section is provided at the front of the cake 12 so as to be openable and closable. The top surface of the cover 16 is provided with a slide insertion hole 16a into which a stick (not shown) such as a thin strip of synthetic resin with a test paper pasted at its tip is inserted. A test paper immersed in blood to cause a color reaction is placed in the measurement section, and the reflectance or transmittance is measured by a light emitting element and a light receiving element (not shown) provided facing the measurement section. Based on these values, the blood sugar level is calculated and displayed on the 9 display 15.

In this invention, the barcode reading section 5 provided on the side of the measuring section cover 16 is important. In the barcode reading section 5, the barcode film 1 is inserted through an insertion passage having an introduction hole 17 and an outlet hole 18. This barcode film 1 is.

A barcode section 3 and an insertion direction indication mark 4 are provided on the upper surface of the film base 2, and the barcode section 5 includes a clock bar section 3a in which bars are provided at equal intervals.
It consists of two tracks: and a data bar portion 3b in which data is recorded. This barcode film 1 is used because the calibration curve table for determining blood sugar levels stored in the circuit of the blood glucose meter 11 needs to be calibrated for each lot of test strips.

Provision is made for inputting this calibration data.

Note that a buzzer 19 is arranged in the cake 12 near the measurement start switch 14. This buzzer 19 is provided to output a sound having a frequency corresponding to the moving speed of the barcode film 1 when reading the barcode.

FIG. 2 is a circuit block diagram of the blood glucose meter.

On/off signals from the power switch 15 and the measurement start switch 14 are taken into the CPU 20. Further, the driver (drive circuit) 21 operates according to a command from the CPU 20, the light emitting element 22 of the measuring section 16 is driven to turn on, and the light projected onto the test strip (not shown) is received by the light receiving element 23. It looks like this. The light receiving current of the light receiving element 23 is as follows.

It is converted into a voltage value by the current/voltage conversion circuit 24, and then A
/ Converted to a digital value by the D converter 25.

It is designed to be taken into the CPU 20.

Further, the ON 488 of the barcode film presence/absence switch 26 provided in the barcode reading section 5 is input to the CPU 20 . In response to the ON signal of this switch 26, the CP
U20 outputs operation commands to drivers 27a and 27b. The drivers 27a and 27b turn on one light emitting element 28a and 28b in response to this operation command.

The light from these light emitting elements 28a and 28b is transmitted to the light receiving element 29n.
, 29b, but the light is blocked by the black part of the barcode film 1. The light receiving current of the light receiving elements 298 and 29b is as follows.

The signals are converted into voltage values by current/voltage conversion circuits 30a and 30b, waveform-shaped by waveform shaping circuits 3fa and 31b, and then taken into the CPU 20. Note that the light-emitting element 28a and the light-receiving element 29a constitute the reading part of the clock bar, and the light-emitting element 28b and the light-receiving element 29b constitute the reading part of the data bar.

Next, follow the flowcharts shown in FIGS. 3 and 4.

The software configuration and operation of the example blood glucose meter will be explained.

When the power switch 16 is turned on, the operation starts, and first, it is determined whether the voltage of the battery (not shown) has become low (decreased below a predetermined value) [step ST (hereinafter referred to as S)].
Abbreviated as T〕1〕. Batch U' with this judgment! If the pressure has decreased below a predetermined value, a battery low indication is displayed on the 1 display 15 (STII). This display is 1, for example, by lighting up a battery-shaped mark.

If the battery voltage is OK in ST1, it is determined whether the memory check is OK (ST2). Here, the memory check means to determine whether or not the contents of the barcode data are backed up in the memory at the time of power failure. If the result of this memory check is OK.

Next, move to ST3, barcode film presence/absence switch 2
6 is turned on or not. When the measurer inserts the barcode film 1 into the insertion path of the barcode reader 5 in order to start using a new lot of test strips, the switch 26 is turned on, so the determination in ST3 is YE.
S, the program moves to 9,5T15 and enters the barcode data reading routine. Details of this routine will be described later.

If the switch 26 is not turned on in ST3, an instruction to use the stick set with the sample paper attached is displayed on the display 15 (ST4).The measurer who sees this display drops blood onto the test paper. At the same time, the measurement start switch 14 is turned on (ST5). In response to turning on the measurement start switch 14, the CPU 20 enters sample measurement (test paper measurement) processing (ST6). Specifically, this sample measurement process starts after a predetermined time (e.g. 1 minute).
The buzzer 19 is turned on to notify blood wiping, and the A/D converter 25 is turned on after a predetermined period of time (for example, 1 minute).
The rice bran pickles are calculated and quantified by referring to the calibration curve table from the received light signal read through the .

Next, check whether there is a sample measurement error or not, that is, the quantitative value is a predetermined value t.
It is determined whether or not it exceeds l- (ST7). If the quantitative value is within the predetermined value, it is assumed that the measurement is normal.

The quantitative value is displayed on the display 15 (ST8). However, if tfiff is within a predetermined value, the measurement is not normal and a sample measurement error is displayed on the 2nd display 15 (ST
9), this completes the measurement of the sample.

Next, the measurement start switch 14 is turned on (ST1
0) and return to ST4 to prepare for the secondary sample measurement.

On the other hand, the result of memory check in ST2.

If the barcode data has not been backed up in memory, the display 15 displays an instruction to insert the barcode film (ST15).

Then, the measurer inserts the barcode film 1 into the barcode reading section 5 after seeing the instruction display.

When the switch 26 is turned on (5T14), the barcode reading routine is moved (ST15). S T 5 To Louis B
When the barcode reading following 5T14 is completed, it is determined whether or not the reading check is OK (ST16>, and if OK, the process moves to ST4 to instruct the test strip setting. If not OK, a reading sheller display is entered on the 1 display 15. No (ST1
7) Inform the measurer. When the measurer sees this display and turns on the measurement start switch 14 (ST18)
, I returned to 5T13 and the display 15 did not display an instruction to insert a barcode film for re-reading.

be done.

Next, the barcode reading routine will be explained. When this routine is entered, as shown in FIG. 4, the signal P10i for driving the buzzer goes high.

pii is low (5T141), and the reading signal of a part of the clock bar, that is, the barcode clock signal is high (5T141).
5T142) If it is No, that is, if it is low (black), the signal P10i is high,
Hold Pll low (see also time 0 in Figure 5).

When the barcode clock signal becomes high, that is, at the rising edge of the clock signal (see time L1 in FIG. 5), the barcode data at that time is read (ST143).

Tsumu υ, if the output of the decoder reader is high.

tt 1tF, if low, input data as °゛0''.

Next, it is determined whether or not the data to be read is the end (ST1
44). In case of termination, return to main flow,
If it is not the end, then signal P10i low, signal P1
1 is high (5T145), and then it is determined whether the barcode clock is low (black) (5T146).

In the case of No, that is, in the case of high (transparent), 5T145
Returning to , the signal P10 remains low and the signal pii remains high. At 5T146, the barcode clock goes low, that is, falls (see time 2 in FIG. 5).

The determination is YES, the process returns to 5T141, and the signal pi is output again.

All high, signal P11 low. Thereafter, the above process is repeated, and each time the barcode clock signal is inverted, the signal P10. P11 is reversed 2 times (5th
L3 in the diagram. (See t4, t5.16...). Also.

Barcode data is read at the rising edge of the barcode clock signal (see t3, t5, etc. in FIG. 5).

Signal P10. P11 is given to the buzzer 19 by the CPU 20, and these two signals cause the buzzer 19 to output the signals P10. It rings at the frequency of P11.

Therefore, barcode film 1 at high speed.

When the barcode clock signal is moved, the frequency of the barcode clock signal increases, and accordingly, the frequency of the signals PIO and P11 also increases, and the sound from the buzzer 19 becomes high-pitched. Conversely, if barcode film 1 is moved at low speed.

barcode clock signal, and signal P10. P11
The frequency of the buzzer 19 becomes low, and the sound from the buzzer 19 becomes low. Therefore, the measurer can hear the sound of the buzzer 19 and know the moving speed of the barcode film.

In the above embodiment, the barcode film is moved relative to the barcode reading section, but the barcode reading section may be moved conversely.

Therefore, the base on which the barcode is attached does not need to be limited to film.

Furthermore, although the above embodiment has been explained using a blood glucose meter as an example, it goes without saying that the present invention can be applied to barcode reading devices for various devices.

(f) Effects of the Invention According to this invention, a sound with a frequency corresponding to the reading speed of the barcode board is output, so that once reading is successful, the sound will have the same tone as the sound at the time of success from the second reading. If you move the barcode plate at a speed of 1, you will have a rough guide and it will be easier to move.

Also, if you try the reading process several times, you will know how fast you should move, so if a reading error occurs no matter how many times you try to move, you can suspect that the barcode board is dirty. Appropriate measures can then be taken.

Furthermore, if a normal barcode board is moved, it will always make a sound, so if no sound is produced, it can be known that there is an abnormality in the barcode board.

[Brief explanation of drawings]

FIG. 1 is an external perspective view of a blood glucose meter in which the present invention is implemented, FIG. 2 is a block diagram showing the circuit configuration of the blood glucose meter, and FIGS. 3 and 4 explain the software configuration and operation of the blood glucose meter. Figure 3 is a main flow diagram, Figure 4 is a flow diagram showing the barcode reading routine, and Figure 5 is a signal waveform time chart used to explain the barcode reading routine. It is. 1: Parcode film, 3a: Part of block bar, 6b: Part of data bar, 5: Barcode reader,
19: Puzar, 20: CPU. 4 Figure 5

Claims (1)

[Claims] (1) A barcode plate on which two tracks are formed, a data bar section and a clock bar section, is scanned relative to the barcode reading section, and the signal of the data bar section is read in synchronization with the reading signal of the clock bar section. A barcode reading device for reading barcodes, comprising an audio output means that is driven in accordance with a reading clock signal of the clock bar section and outputs audio at a frequency corresponding to the scanning speed of the barcode plate. Device.