JPS592596Y2 - Input panel electrode - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electrode structure in a double matrix tablet type input device.

The inventor of this invention has already proposed a double-matrix tablet-type input device (Japanese Patent Application Laid-Open No. 55-41542), but this invention has improved the electrode configuration to prevent erroneous input. It is something.

First, the principle of the double matrix tablet type input device will be explained using FIGS. 1 and 2.

Figure 1 shows the circuit of only the matrix rows of a double matrix tablet input device.
5 A12...”mn, bll 1 b215
``'bnm is an electrode that constitutes each row, and a set of these electrodes (all.

1)o)t(at□, 1)zt)+...'t(am
n, anm, and V7'mn sets are provided.

These electrode groups are divided into m groups of n electrodes, and within each group, electrodes ai19 ai2...
ain (where i means the i-th group) are all connected in parallel, AI, A2, A3,...
・, At, ... Am terminals are provided.

On the other hand, the electrodes in each group are sequentially 1.2.3. ...
The b electrodes bll, b12,...bin of all groups with the same numbers are all connected in parallel by the multi-wire 2 to form B□, B2...n.・・・
・,B1. ..., provide a Bn terminal.

By this connection, mn sets of electrode groups are arranged in an mxn matrix.

i.e. electrode silk (all, bll), (A12.1)
21) t・”'(alntbnl)+ ・・”9(
A21, b12) t"', (ar#n, b
(nm) Arrange so that it can be used.

If electrodes a and 6 are short-circuited with a conductor at any point of any one of these electrode groups,
The terminals of group A and group B to which the electrodes of that set are connected become electrically connected.

The combination of terminals of group A and group B that are conductive is short-circuited electrode a
, l) corresponds one-to-one.

Therefore, by detecting the combination of terminals of group A and group B that are conducting by the detection circuits 3 and 4, the set of electrodes a is short-circuited.

The coordinates of b can be identified.

This electrode a. 6 can be short-circuited using a metal contact, a conductive elastic body, or the like.

Figure 2 shows two electrode groups arranged and wired in Figure 1.
This figure shows an example of the arrangement of electrodes of an input device configured as a double matrix array arranged orthogonally in groups, where 5 is a flexible insulating plastic film, pressure-sensitive conductive rubber, or the like.

The intersection points of the electrode group of electrodes a and b and the electrode group of electrodes a' and b' are arranged in a matrix.

Since these electrodes a, l) and a', b' are connected in a matrix, these intersection points are double-wired when viewed from the terminals A group, B group, A' group, and B' group. This means that they are arranged in a matrix.

At the intersection of the set of electrodes a and b and the set of electrodes a' and b', short-circuit the electrodes of both sets respectively (if 5 is an insulating sheet) or press down the intersection point (if 5 is a sensitive In the case of pressure conductive rubber), the coordinates of this intersection point can be identified by detecting the combination of terminals of group A and group B that are electrically connected and the combination of terminals of group A and group B' that are electrically conductive.

That is, when pulses are sequentially applied to terminals A1, A2, . . . Am, and pulses are detected on the B side, B1. B2...
By identifying which terminal of B and at which timing a pulse was detected, the set of electrodes a and l) that are in a conductive state can be determined.

Next, pulses are applied to terminals AI', A2'...A, r1' in this order, and when a pulse is detected on the B' side, B1', B2'.

By identifying which terminal of Bn' and at which timing the pulse was detected, the set of electrodes a' and b' which are in a conductive state can be determined.

Therefore, the coordinates of the conducting crossing points are identified.

Looking at the electrode arrangement in the double matrix tablet type input device shown in FIGS. 1 and 2 above, terminals Bn
The electrode connected to, for example, bin is adjacent to the electrode a1n connected to the terminal A1 with which it is originally combined, and
It is also adjacent to the electrode a2□ connected to the other terminal A2.

Therefore, for example, when the intersection 6 in FIG. 2 is pressed down, the electrode bn
1 is electrically conductive with the electrode a1n, resulting in electrical continuity between the terminals A1 and Bn, and may also be electrically conductive with the electrode a21.

Therefore, in that case, terminals A2 and B, which should not be electrically connected,
It will also be electrically connected to n.

The conduction between the terminals A2 and Bn is also caused by the combination of the electrodes a2n and Bn2.

Therefore terminals A2 and B.

The combination is a combination of electrodes a1o and bnl, and electrode a2n.

Two different coordinates corresponding to the two combinations of 2 and 2 are detected by the same terminal.

This causes incorrect input.

Therefore, the present invention proposes terminal A1. A2...any 1 of Am
Book and terminal B1. All combinations with any one of B2...B, and adjacent combinations of electrodes a, l) (all,
1) n), (al2.

b2□), -..., (a nmt, b m n) as 1
The purpose of this method is to prevent two different coordinates on the board from being detected by the same terminal.

The present invention will be explained in detail below with reference to the figures. FIG. 3 is a diagram showing an embodiment of the present invention.

Only the lateral electrodes are shown.

Electrode a1□, al. ...aln, al (n teni
) are the electrodes connected to terminal A1, b1□, b21
．． b3, . . . bnl are the respective terminals B1. B2. B.

The electrode is connected to the

Electrodes a1□ and a-work 2 sandwich electrode b1□.
1□ and al3 are electrode a1n so as to sandwich electrode b21.
and al(n +1 ) are adjacent to each other so as to sandwich the electrode bn1.

Therefore, the area sandwiched between electrodes a1□ and a1□ is A1 and B1.
The area between electrodes a1□ and al3 is the area where A1 and B2 are adjacent, and the area between electrodes aln and al(n+□
) is the area adjacent to A□ and Bn.

Since there is an electrode connected to A1 between the electrode connected to Bn and the electrode a2□ connected to A2, the electrode bnl is connected to terminal A1 as in the case of Fig. 1. No defects occur adjacent to both the electrode connected to terminal A2 and the electrode connected to terminal A2.

Therefore, there is only one adjacent region of the electrode that conducts A2 and Bn, and two separate and different coordinates will not be detected from the same terminal as in the case of Figure 1. .

FIG. 4 is a diagram showing another embodiment of the present invention.

The electrode portion connected to terminal A1 in FIG. 2 is shown as an example.

The area where terminals A1 and B1 are adjacent is the electrode al'l
t(all)? (all)' 5 al2
and b1□, (b1□), Cb1□), and when an input panel as shown in FIG. 1 is configured, there is an advantage that adjacent electrodes are easily short-circuited when pressed.

FIG. 4 is a diagram showing another embodiment of the present invention.

There are arranged electrodes 7 and 8 on the electrodes a1□, a1□, and b1□, and when pressed down, adjacent electrodes are likely to be short-circuited.

In the above, only the horizontal electrode was explained.
The vertical electrodes are also constructed in the same manner.

As is clear from the above description, according to the electrode configuration of the present invention, the coordinates on the board always correspond 1:1 to the combination of terminals, and erroneous input does not occur.

Therefore, there is no inconvenient location when pressing down on the board surface, making it possible to realize an input board that is easy to operate.

[Brief explanation of drawings]

1 and 2 are diagrams for explaining the principle and electrode configuration of a conventional double-matrix tablet type input panel, and FIGS. 3 to 5 are diagrams showing embodiments of the present invention. all 1 a121~a1n, al (n+1)
9(all)5(all)...electrodes connected to terminal A1, a21 to a2n, a2(n+x)・
...Electrodes connected to terminal A2, bl, 15b12-b
,,, (b,1), C,b,,)...electrode connected to terminal B1, bn work, bn2~b work...terminal B
Electrode connected to n, 7.8... Whisker-shaped electrode.

Claims (1)

[Scope of utility model registration request] It has first electrodes (all, A12, am n) and second electrodes (b, 1゜b1□,...b, m), with the first electrodes arranged in rows and the second electrodes arranged in columns. The electrode silk (a
llt b1□)b(A12゜b21),...”(an
m, amn) and a second electrode group having the same configuration as this, one electrode group is a row,
In the input panel electrode of a double matrix tablet type input device in which the other electrode is arranged in a row and the intersection points of the electrodes are configured in a double matrix, an additional electrode (al(n+1)9A2) is used as the first electrode. (n-h)t'-
am(n+i), and an electrode arrangement in which all the second electrodes are sandwiched between the first electrodes.