JPH01161783A - Lighting circuit for light emitting diode - Google Patents

Abstract

PURPOSE:To enable the number of controllable light emitting diodes to be increased without the number of terminals being increased, by a structure wherein light emitting diode parallel circuit groups in which at least one light emitting diode is connected in opposite polarity are connected between a first and second light emitting diode flash controlling terminal groups, each the light emitting diode flash controlling terminal having three potential states. CONSTITUTION:A plurality of first light emitting diode flash controlling terminals D1-DM each of which has three states consisting of a first potential state, a second potential state and a high impedance state, respectively, a plurality of second light emitting diode flash controlling terminals S1-SN each of which has said three states, and light emitting diode parallel circuit groups (G11, R11)-(GMN, RMN) which are connected between said plurality of first and second light emitting diode flash controlling terminals D1-DM and S1-SN, respectively, are provided. Now, each of said light emitting diode parallel circuit groups consists of a plurality of light emitting diodes, and at least one light emitting diodes out of them are connected with the other light emitting diodes in parallel-opposition. For example, a first and second flash controlling terminals D1-DM, S1-SN are used as digit output terminals and segment output terminals, respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention relates to a light emitting diode lighting circuit used for displaying numbers in digital watches and the like.

[Conventional technology]

FIG. 3 is a circuit diagram showing a light emitting diode lighting circuit conventionally known as a cathode common type dynamic lighting circuit. In the figure, 1a to 1C are p-channel enhancement type gold Jffiff film semiconductor transistors (hereinafter abbreviated as p-MO8T), and their sources are connected to the high potential side.

The drain of p-MO3T1a is the segment output terminal SR
1 and red light emitting diodes R5, R8, through resistor ra.
R11(7)7/-, the drain of p-MO3T1b is connected to the anode of red light emitting diodes R8, R9゜R12 via segment output terminal SR2 and resistor r, p-M
The drain of O8T1c is the segment output terminal SR3 and the resistor r. Through the red light emitting diode R7, RIO, R1
3 anodes, respectively. and p-MO8
T1a to 1C apply oNloFF to the segment signal 5EG-R1 input to each gate according to R3, and set the output state of the segment output terminals SRI to SR3 to a high impedance state or a high potential state. 2a to 2C are n-channel enhancement type metal oxide film semiconductor] transistors (hereinafter abbreviated as n-MO8T), and their sources are connected to the low potential side. The drain of n-MO8T2a is connected to the cathodes of red light emitting diodes R5 to R7 via the digit output terminal A1, the drain of n-MO8T2b is connected to the cathodes of red light emitting diodes R8 to R10 via the digit output terminal A2, and the drain of n-MO8T2c is connected to the cathodes of red light emitting diodes R5 to R7 via the digit output terminal A2. The digit output terminal A3 is connected to the cathodes of red light emitting diodes R11 to R13, respectively. And n-MO8T2a to 2C are digit signals input to each gate [)igit-R1-R3
Accordingly, the output state of the digit output terminals A1 to A3 is set to a high impedance state or a low potential state.

Then, the red light emitting diodes R5 to R13 are caused to blink based on the combination of the output states of the segment output terminals SR1 to SR3 and the digit output terminals A1 to A3.

FIG. 4 is a circuit diagram showing a conventional light emitting diode lighting circuit with a configuration similar to that of FIG. The potential side is switched, and the connection of the light emitting diode is also reversed accordingly. In addition, red light emitting diodes R5 to R13
Instead, green light emitting diodes 05 to G13 are used.

Next, the operation will be explained. First, FIG. 3 will be explained. Now, when segment signal 5EG-R1 is “0■”, p-MO8T1a is conductive and segment output terminal SR
1 is a high potential. Therefore, if the digit signal [)igit-R1 is "5V", the n-MO8T2a becomes conductive and the digit output terminal A1 becomes a low potential, and a current flows through the red light emitting diode R5, which lights up. Also, the digit signal Qigit-R2 is “
5V", the digit output terminal A2 becomes a low potential, the red light emitting diode R8 lights up, and the digit signal Qigit-R3 becomes "5V".
v'', the digit output terminal A3 becomes a low potential and the red light emitting diode R11 lights up.

Similarly, when the segment signal 5EG-R2 is "0■", if the digit signal Qigit-R1 is "5v", the red light emitting diode R6 is activated, and the digit signal [)igit・R2 is "5V".
Then, the red light emitting diode R9 outputs the digit signal Qigit-R.
3 is '5 V', red light emitting diodes R12 each light up.Similarly, when the segment signal 5EG-R3 is 'OV', if the digit signal Diait-R1 is '5V', the red light emitting diode R7 turns on the digit signal [ ]1g1t-R2
is “5V”, red light emitting diode R10 outputs digit signal D
When IQit-R3 is 5 V'', red light emitting diodes R13 are turned on.

Note that the segment signals 5EG-R1-R3 are “5V” r
When p-MO8T, 1a to 1c are turned off, segment output terminals SR1 to SR3 become in a high impedance state, and red light emitting diodes R5 to R13 do not light up regardless of the output states of digit output terminals A1 to A3. vice versa,
The digit signal Qigit・R1-R3 is 'ov' and n-
If MO8T2a ~ 2c is OFF, digit output terminal A1 ~
A3 becomes a high impedance state, and the red light emitting diodes R5 to R13 do not light up regardless of the output states of the segment output terminals SRI to SR3. In other words, in the combination of the output states of segment output terminals SR1 to SR3 and digit output terminals A1 to A3, one of the red light emitting diodes R5 to R13 lights up only when the former is at a high potential and the latter is at a low potential. .

Here, the number of segment output terminals is N, and the number of digit output terminals is M.
In this case, (NXM) light emitting diodes can be controlled. FIG. 5 is a timing diagram showing an example of the above operation.

In the circuit shown in Figure 4, segment output terminal S
In the combination of output states of G1 to SG3 and digit output terminals 81 to 83, the former has a low potential (i.e. segment signal @5
When EG-Gl~G3 is '5 V''), the latter is at a high potential (that is, the digit signal Diqi t-G1~G3
KA” OV ” (7) J knee ki) (7) ji
Case (7) One of the green light emitting diodes 05 to G13 lights up. In this case as well, if the number of segment output terminals is N and the number of digit output terminals is M, (NXM) light emitting diodes can be controlled.

[Problem that the invention seeks to solve]

Since the conventional light emitting diode lighting circuit is configured as described above, when trying to control (2XNXM) light emitting diodes, for example, in the circuit shown in FIGS. 3 and 4, red light emitting diodes R5 to R13 are controlled. The terminal to control (
terminals (SG1 to SG3 and B) that control the green light emitting diodes G5 to G13).
1 to B3) are separate, so the control terminals are 2 (N+M
), resulting in an increase in the number of control terminals.

This invention was made to solve the above-mentioned problems, and an object thereof is to obtain a light emitting diode lighting circuit that can increase the number of light emitting diodes that can be controlled without increasing the number of terminals.

[Means for solving problems]

A light emitting diode lighting circuit according to the present invention includes a plurality of first light emitting diode blinking control terminals each having three states: a first potential state, a second potential state, and a high impedance state; A plurality of second light emitting diode blinking control terminals, and a light emitting diode parallel circuit body connected between the plurality of first and second light emitting diode blinking control terminals, each of the light emitting diode parallel circuit bodies It consists of a plurality of light emitting diodes, at least one of which is connected in parallel with the other light emitting diodes with opposite polarity.

[Effect]

The first and second light emitting diode blinking control terminals in this invention each have three states: a first potential state, a second potential state, and a high impedance state, and the combination of these allows the light emitting diode parallel circuit to be formed. Make the constituent light emitting diodes blink.

〔Example〕

FIG. 1 is a circuit diagram showing a light emitting diode lighting circuit according to an embodiment of the present invention. In the figure, i, 8 (i=1
~N) is a p-MO8T whose source is connected to the high potential side and whose segment signal 5EG-i is input to the gate.
It is 0N10FF according to 0V15V. 'ns is n
-MO8T with source on low potential side and drain on p
-0V15 which is the segment signal 5EG-1n connected to the drains of MO8Ti and S respectively and input to the gate.
0FF10N according to V. p-MO8Ti, 8 and n
-MO8Ti,3's drain common connection point is connected to the segment output terminal 3i. Segment output terminal Si
becomes a high potential when only p-MO8Ti, 3 is ON, and becomes a low potential when only MOS T i nS is ON, and p-MO8Ti, S and n-MO8Ti
When both o8 are turned off, it becomes a high impedance state.

j, o (j = 1 to M) are p-vosr, the source is connected to the high potential side, and the digit signal @GDj input to the gate
It is 0N10FF according to 0V15V. jnD is n
-MO8T with source on low potential side and drain on p
-M OS T jp. are respectively connected to the drains of the gates, and turn 0FF10N in response to 0V15V, which is the digit signal RDj input to the gates.

The drain common connection point of p-MO8TJPD and n-MO8Tjop is connected to the digit output terminal Dj.

For the digit output terminal Dj, only MO8TjpO is ON.
Then, the potential becomes high, and when only n-MO8Tjo is turned on, the potential becomes low, pMO8TJpO and n-MO8
When both Tj and D are turned off, a high impedance state occurs.

The digit output terminal Dj is connected to one end of a parallel circuit body in which two green and red light emitting diodes Gji and Rji are connected in parallel with opposite polarities, and the segment output terminal Si is connected to the other end of the parallel circuit body through a resistor R1. connected to the end. Specifically, the digit output terminal Dj is a green light emitting diode G.
The segment output terminal 3i is connected to the cathode of the green light emitting diode Gj1 and the anode of the red light emitting diode Rji through a resistor Ri.

When the digit output terminal Dj is at a high potential and the segment output terminal Si is at a low potential, the green light emitting diode Gj1 lights up, and in the opposite case, the red light emitting diode Rji lights up. Furthermore, when the segment output terminal 3i is in a high impedance state, the light emitting diodes Gji and Rji do not light up regardless of the state of the digit output terminal Dj, and also when the digit output terminal Dj is in a high impedance state, the segment output terminal Si does not light up. Light emitting diode Gji regardless of output status
and Rjl do not light up.

Next, the operation will be explained. Segment signal 5EG-1
o and 5EG-1p are "5VnF digits [GDj and RDJ
If is "OV", the segment output terminal Si has a low potential and the digit output terminal Dj has a high potential, so that the designated green light emitting diode Gji lights up. Next, segments 5EG-t and 5EG-in are “ov” and the digit signal RD
If j and GDj are "5V", the segment output terminal S1 has a high potential and the digit output terminal Dj has a low potential, so that the designated red light emitting diode Rji lights up.

Segment signal 5EGip is 5■”, segment 5EG
When i is “0■”, p-Mo5T' ps and n
Since both MOS T + nS are turned off, the segment output terminal Si is in a high impedance state, and the light emitting diodes Gji and Rjl do not light up regardless of the state of the digit output terminal Dj. Furthermore, when the digit signal GDj is "'5V" and the digit signal RDj is Ov, both pMO8TJp□ and n-MO8Tjo□ are turned off, so the digit output terminal D
j is in a high impedance state, and the light emitting diodes Gji and Rj are in a high impedance state regardless of the state of the segment output terminal Si.
i does not light up. Here, the number of segment output terminals is N,
If the number of digit output terminals is M, then (2xNxM) light emitting diodes can be controlled.

FIG. 2 is a timing diagram showing an example of the above operation.

In the above embodiment, the circuit was constructed using CMOS transistors, but the same effects as in the above embodiment can be obtained even if bipolar transistors are used.

Further, in the above embodiment, two light emitting diodes are connected with opposite polarity to form a parallel circuit, but a parallel circuit can be formed by using three or more light emitting diodes and connecting at least one of them with reverse polarity. It may also constitute a body.

〔Effect of the invention〕

As described above, according to the present invention, the first potential state, the second
A first light emitting diode blinking control terminal and a second light emitting diode blinking control terminal having three states, a potential state and a high impedance state, are provided, and a plurality of light emitting diodes are connected in parallel between these terminals, and at least one of them is connected in parallel. Since a light emitting diode parallel circuit body in which one light emitting diode is connected with the opposite polarity to another light emitting diode is connected, there is an effect that the number of light emitting diodes that can be controlled with the same number of terminals as in the conventional method can be increased.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing a light emitting diode lighting circuit which is an embodiment of the present invention, Fig. 2 is a timing diagram of the operation in the circuit of Fig. 1, and Fig. 3 is a circuit diagram showing a conventional light emitting diode lighting circuit. , FIG. 4 is a circuit diagram showing another conventional light emitting diode lighting circuit, and FIG. 5 is a timing diagram of the operation of the circuit of FIG. 3. In the figure, D1 to DM are digit signal output terminals, 81 to SN
are segment output terminals, 011~GMN and R11~R
MN is a light emitting diode. Note that the same reference numerals in each figure indicate the same or corresponding parts. Agent Masuo Oiwa Figure 2 Figure 3 Figure 4 Figure 5 Procedural amendment (voluntary) Showa year, month, day

Claims (1)

[Claims] (1) A plurality of first light emitting diode blinking control terminals having three states: a first potential state, a second potential state, and a high impedance state; and a plurality of second light emitting diode blinking terminals having the three states. a control terminal; and a light emitting diode parallel circuit body connected between the plurality of first and second light emitting diode blinking control terminals,
A light emitting diode lighting circuit in which each of the light emitting diode parallel circuit bodies includes a plurality of light emitting diodes, and at least one of the light emitting diodes is connected in parallel with the other light emitting diodes with opposite polarity.