JPH084154B2 - Light emitting diode lighting circuit - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a light emitting diode lighting circuit used for numeric display of a digital timepiece.

[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 metal oxide semiconductor transistors (hereinafter p-
Abbreviated as MOST. ), And the sources are connected to the high potential side, respectively. The drain of p-MOST1a is a segment output terminal
SR1 and resistance r _a of the through red LED R5, R8, to the anode of R11, the drain of the p-MOST1b segment output terminal
The red light emitting diode R6, R9, R12 anode is connected via SR2 and resistor r _b, and the drain of p-MOST1c is a segment output terminal.
The red light emitting diodes R7, R10, and R13 are respectively connected to the anodes through SR3 and the resistor r _c . And p-MOST1a ~
1c is the segment signal SEG ・ R1 input to each gate
Turns ON / OFF according to ~ R3, and sets the output state of the segment output terminals SR1 to SR3 to the high impedance state or high voltage state. Reference numerals 2a to 2c are n-channel enhancement type metal oxide semiconductor transistors (hereinafter abbreviated as n-MOSTs), the sources of which are connected to the low potential side. The drain of the n-MOST2a is connected to the cathode of the red light emitting diodes R5 to R7 via the digit output terminal A1, the drain of the n-MOST2b is connected to the cathode of the red light emitting diodes R8 to R10 via the digit output terminal A2, and the n-MOST2c.
The drain is connected to the red output diode R1
To R13 cathodes. And n-MOS
T2a ~ 2c are digit signals Digit ・ R1 ~ input to each gate
Turns ON / OFF according to R3, and sets the output state of digit output terminals A1 to A3 to high impedance state or low potential state. And
Output status of segment output terminals SR1 to SR3 and digit output terminal A1
The red light emitting diodes R5 to R13 are made to blink by the combination of ~ A3.

FIG. 4 is a circuit diagram showing a conventional light emitting diode lighting circuit having a configuration similar to that of FIG. 3. In this conventional example, p-MOST and n-MOST in the conventional circuit of FIG. The potential side is replaced and the connection of the light emitting diode is reversed accordingly. Further, green light emitting diodes G5 to G13 are used instead of the red light emitting diodes R5 to R13.

Next, the operation will be described. First, FIG. 3 will be described. Now, assuming that the segment signal SEG ・ R1 is "0V", p-
MOST1a becomes conductive and the segment output terminal SR1 becomes high potential. Therefore, if the digit signal Digit-R1 is "5V", n-MOST2a
Is turned on, the digit output terminal A1 becomes low potential, current flows through the red light emitting diode R5, and R5 is lit. Also, the digit signal Digit ・ R
When 2 is "5V", the digit output terminal A2 is at a low potential and the red light emitting diode R8 is lit, and when the digit signal Digit R3 is "5V", the digit output terminal A3 is at a low potential and the red light emitting diode R11 is lit.

Similarly, when the segment signal SEG ・ R2 is "0V", the red light emitting diode R6 is used when the digit signal Digit ・ R1 is "5V" and the red light emitting diode R9 is used when the digit signal Digit ・ R2 is "5V".・ If R3 is "5V", red LED R12 lights up. Similarly, when the segment signal SEG / R3 is "0V", if the digit signal Digit / R1 is "5V", the red light emitting diode R7
However, if the digit signal Digit R2 is "5V", the red light emitting diode R1
If 0 is digit signal Digit R3 is "5V", red light emitting diode R
13 lights up.

When the segment signals SEG ・ R1 to R3 are "5V", p-MOST
When 1a to 1c are turned off, the segment output terminals SR1 to SR3 are in a high impedance state, and the red light emitting diodes R5 to R13 are not turned on regardless of the output states of the digit output terminals A1 to A3. On the contrary, when the digit signal Digit ・ R1 ～ R3 is "0V", n-MOST2a ～
When 2c is turned off, the digit output terminals A1 to A3 are in a high impedance state, and the red light emitting diodes R5 to R13 are not turned on regardless of the output states of the segment output terminals SR1 to SR3. That is, segment output terminals SR1 to SR3 and digit output terminals A1 to A3
In the combination of the output states, any one of the red light emitting diodes R5 to R13 is lit only when the former is at high potential and the latter is at low potential.

Here, assuming that the number of segment output terminals is N and the number of digit output terminals is M, (N × M) light emitting diodes can be controlled. FIG. 5 is a timing chart showing an example of the above operation.

In the circuit shown in FIG. 4, segment output terminals
In the combination of SG1 to SG3 and digit output terminals B1 to B3, the former is low potential (that is, segment signals SEG ・ G1 to G3).
When 3 is “5V”, the latter is high potential (ie digit signal Digi
t ・ G1 to G3 is "0V"), one of the green LEDs G5 to G13 lights up. Also in this case, if the number of segment output terminals is N and the number of digit output terminals is M, (N × M) light emitting diodes can be controlled.

[Problems to be solved by the invention]

Since the conventional light emitting diode lighting circuit is configured as described above, if it is attempted to control (2 × N × M) light emitting diodes, for example, in the circuits shown in FIG. 3 and FIG. Terminals that control R5 to R13 (SR1
~ SR3 and A1 to A3) and the terminals (SG1 to SG3 and B1 to B3) for controlling the green light emitting diodes G5 to G13 are separate,
There is a problem in that the number of control terminals is 2 (N + M), which increases the number of control terminals.

The present invention has been made to solve the above problems, and an object thereof is to obtain a light emitting diode lighting circuit capable of increasing the number of controllable light emitting diodes without increasing the number of terminals.

[Means for solving problems]

A light-emitting diode lighting circuit according to the present invention has a first potential state, a second potential state and a high impedance state.
Between a plurality of first light emitting diode blinking control terminals having one state, a plurality of second light emitting diode blinking control terminals having the three states, and a plurality of the first and second light emitting diode blinking control terminals And a light emitting diode parallel circuit connected to each other. Each of the light emitting diode parallel circuits is composed of a plurality of light emitting diodes, at least one of which is connected in parallel with another light emitting diode in reverse polarity.

[Action]

The first and second light emitting diode blinking control terminals in the present invention each have three states of a first potential state, a second potential state and a high impedance state, and by combining these three states, a light emitting diode parallel circuit body is formed. Blinks the light-emitting diode that constitutes it.

〔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 _PS (i = 1
~ N) is a p-MOST, the source of which is connected to the high potential side and is a segment signal SEG · i _P to be input to the gate 0
Turns ON / OFF according to V / 5V. i _nS is an n-MOST, the source is connected to the potential side, the drain is connected to the drain of the p-MOSTi _PS , and the segment signal SEG · i _n is input to the gate.
OFF / ON according to 0V / 5V. p-MOSTi _PS and n-MO
The common drain connection point of _STInS is connected to the segment output terminal Si. Segment output terminal Si is p-MOSTi
_When only _PS turns on, the potential becomes high, and only n-MOSTi _nS turns on.
Then, the potential becomes low, and both p-MOSTi _PS and n-MOSTi _nS
When it is turned off, it enters a high impedance state.

j _PD (j = 1 to M) is p-MOST, the source is connected to the high potential side, and the digit signal GDj is input to the gate 0
Turns ON / OFF according to V / 5V. j _nD is an n-MOST, the source is connected to the low potential side, the drain is connected to the drain of the p-MOSTj _PD , and the digit signal RDj input to the gate is 0V / 5V.
OFF / ON according to. The common drain connection point of p-MOSTj _PD and n-MOSTj _nD is connected to the digit output terminal Dj. The digit output terminal Dj becomes a high potential when only the p-MOSTj _PD is turned on, and becomes a low potential when only the n-MOSTj _nD is turned on, and the p-MOS
When both Tj _PD and n-MOSTj _nD are turned off, a high impedance state is set.

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 in opposite polarities, and the segment output terminal Si is connected to the other side of the parallel circuit body via a resistor Ri. Connected to the end. Specifically, the digit output terminal Dj is connected to the green light emitting diode Gji anode and the cathode of the red light emitting diode Rji, and the segment output terminal Si is connected to the green light emitting diode Gji via the resistor Ri.
Of the red light emitting diode Rji. When the digit output terminal Dj has a high potential and the segment output terminal Si has a low potential, the green light emitting diode Gji
Lights up, and vice versa, the red light emitting diode Rji lights up. When the segment output terminal Si is in the 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 the digit output terminal Dj
Segment output terminal Si
The light emitting diodes Gji and Rji do not light up regardless of the output state of.

Next, the operation will be described. Segment signal SEG · i _n
If SEG · i _P is “5V” and the digit signals GDj and RDJ are “0V”, the segment output terminal Si is at low potential and the digit output terminal Dj is at high potential, so the designated green light emitting diode Gji
Lights up. Next, the segments SEG · i _P and SEG · i _n are “0V” and the digit signals RDj and GDj are “5V”, and the segment output terminal Si is at high potential and the digit output terminal Dj is at low potential. The red light emitting diode Rji lights up.

Segment signal SEGi _P is “5V” and segment SEGi _n is “O”
In the case of V ", both p-MOSTi _PS and n-MOSTi _nS are turned off, so the segment output terminal Si is in a high impedance state, and the light emitting diode is independent of the status of the digit output terminal Dj.
Gji and Rji do not light up. When the digit signal GDj is "5V" and the digit signal RDj is "OV", both p-MOSTj _PD and n-MOSTj _nD
Since it is turned off, the digit output terminal Dj is in a high impedance state, and the light emitting diodes Gji and Rji do not light regardless of the state of the segment output terminal Si. Here, if the number of segment output terminals is N and the number of digit output terminals is M, (2 × N
XM) light emitting diodes can be controlled.

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

Although the circuit is formed by using the CMOS transistor in the above-mentioned embodiment, the same effect as that in the above-mentioned embodiment can be obtained by using the bipolar transistor.

Also, in the above embodiment, two light emitting diodes are connected in reverse polarity to form a parallel circuit body, but three or more light emitting diodes are used and at least one light emitting diode is connected in reverse polarity to form a parallel circuit. The body may be configured.

〔The invention's effect〕

According to the invention as described above, the first potential state, the second potential state
A first light emitting diode blinking control terminal and a second light emitting diode blinking control terminal having three states of a potential state and a high impedance state, and a plurality of light emitting diodes are connected in parallel between these terminals, and at least one of them is provided. One of them is connected to the light emitting diode parallel circuit body which is connected to the other light emitting diode in the opposite polarity, so that it is possible to increase the number of light emitting diodes which can be controlled with the same number of terminals as the conventional one.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a light emitting diode lighting circuit according to an embodiment of the present invention, FIG. 2 is a timing diagram of operation in the circuit, 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 chart of the operation in the circuit of FIG. In the figure, D1 to DM are digit signal output terminals, S1 to SN are segment output terminals, and G11 to GMN and R11 to RMN are light emitting diodes. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Claims] 1. A plurality of first light emitting diode blinking control terminals having three states of a first potential state, a second potential state and a high impedance state, and a plurality of second light emitting states having the three states. A diode blinking control terminal; 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 comprises a plurality of light emitting diodes, at least one of which is connected in parallel with another light emitting diode in reverse polarity and a light emitting diode lighting circuit.