KR920009208B1 - On-off apparatus for digital controller - Google Patents

Abstract

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Description

On-off device for digital controller

Shows an illustration of a remote control transmitter for a consumer appliance having an on-off circuit embodying the present invention.

The present invention relates to an on-off device for a digital controller, such as a microprocessor, which controls the operation of a remote transmitter in a consumer appliance.

The remote transmitter of a consumer appliance, such as a color television set or video disc player, is a battery operated and controlled in operation by a microprocessor. To conserve power in the battery, the remote transmitter is powered only during that interval when the command signal of the instrument's remote receiver circuit is generated by the transmitter.

In a typical keyboard transmitter device, an electrically conductive contact sheet is connected to the electrical ground. Each keyboard switch is located on the contact sheet, spaced apart from the contact sheet. The signal line from the input port of the microprocessor is connected to the keyboard switch.

When a keyboard switch corresponding to a given function or command to be transmitted is pressed, the switch is electrically connected to a grounded contact sheet, which grounds the signal and wires connected to that switch. The input ports or ports of the microprocessor that are connected to the signal line are grounded to provide instructions to the microprocessor to which specific instructions are sent.

In order to power the microprocessor when either of the keyboard switches is pressed, each signal line connected to the switch is also connected to the control terminal of the on-off transistor switch. The collector-to-emitter path of the transistor is connected between the capacitor and the microprocessor's voltage supply, which produces an operating voltage of 6.3 volts. When the signal line is grounded to the contact sheet, the control terminal of the on-off transistor switch is also grounded to enable the transistor to be turned on and main power supplied from the battery to the voltage supply terminal of the microprocessor.

After the command has been sent by the remote transmitter, it is desirable to interrupt power to the circuitry of the microprocessor and associated transmitter to conserve power in the battery. The microprocessor itself issues a power down command signal by internally grounding the output port.

The operating characteristics of the microprocessor, such as the ability of the output port to sink current, can become unpredictable when the voltage at the supply terminal attenuates below a given value, such as 4.5 volts or less.

A feature of the present invention is a latching device that ensures reliable microprocessor turn-off by reliably holding the on-off transistors at the breakpoint for the entire interval of supply voltage attenuation to zero volts. The off-command of the microprocessor is applied to the control terminal of the latch and the keyboard switch input signal line is connected to the other control terminal of the latch. The main current terminal of the latch is coupled to the control terminal of the on-off transistor switch.

Grounding the input signal line makes it possible to flow a base current to activate the latch and to turn on the on-off transistor switch. The off command signal from the microprocessor disables the latch and prevents base current from flowing within the on-off transistor switch to power down the microprocessor. Due to the on-off latch control device, the power of the battery is conserved because the battery is connected to the voltage supply terminal of the microprocessor only during the generation of the command signal. In addition, reliable self-turn off or self-power down of the microprocessor ensures once the off-command signal is generated.

In the remote transmitter 10, the controlled microprocessor, and the battery operated in the figure, each contact switch 21 of the keyboard assembly 20 contacts a plurality of input ports IN of the microprocessor 25, which is a digital controller. It is coupled to one or more signal lines (SI) connecting the switches. As an example, only four signal lines and input ports are shown in the figure. In fact, it is provided between 10 and 20 signal lines and the input port. The microprocessor 25 may be selected such as a COP 420L manufactured by National Semiconductor Corporation of Santa Clara, California.

The keyboard assembly 20 has an electrically conductive contact sheet 22 electrically connected to the ground terminal of the remote transmitter circuit. Alternatively, the contact sheet 22 may be constructed of a plastic, such as a nonconductive sheet printed on the contact sheet and having electrically conductive conductor wires electrically connected to ground. The contact sheet 22 is placed below and spaced apart from each contact switch 21. Pressing the contact switch grounds the corresponding input line or ports by grounding the associated signal line or lines.

When the remote transmitter is part of a remotely controlled television receiver, it may be the same as a "channel scan" for continuous selection of channels, or as a "play" or "pause" command signal for playback, regular and start-up. To transmit a command signal, when the remote transmitter is part of a remote controlled video disc or tape player, the operator presses an appropriate one of the contact switches 21 representing the command signal to be transmitted. The corresponding signal line or lines SI are grounded, thereby grounding the corresponding input port IN.

The microprocessor 25 determines the switching state of the input port IN. Upon determining whether a particular combination of input ports is in a low or ground state, the microprocessor 25 generates an encoded pulse of serial flow at the output port SK corresponding to the command selected by the operator. The pulse is applied to the transmitter 26 of the remote transmitter 10. When output port SK is in a low state, the port is grounded through the conductive source-drain path of the MOS transistor of the output interface circuit associated with the port, although not shown in the figure. Therefore, when the transistors Q1 and Q2 are cut off, current is prevented from flowing in the light emitting diode OR. When the output port SK is in a high state, the transistor Q1 is turned on to turn on the transistor Q2 to flow a current in the light emitting diode CR. In this way, the coded signal pulses at terminal SK representing a given command are converted by the light emitting diode converter into coded optical pulses for reception at the remote receiver.

Main power for the remote transmitter 10 is obtained from the capacitor 23. Power is supplied through main current conduction, on-off collector-to-emitter path, PNP, and switching transistor Q3.

The collector of transistor Q3 is coupled to the base of transistor Q1. The collector of transistor Q3 is also coupled to a Vcc voltage supply terminal that supplies power to microprocessor 25 to control the activation of transmitter 26.

In the interrupted state of the power of the remote transmitter 10, the transistor Q3 enters a non-conductive state and disconnects the capacitor 23 from the control terminals of the microprocessor 25 and the transmission unit 26. Substantial power is not drained from the battery 23 in a state where power is interrupted.

The remote transmitter 10 is powered when the contact switch 21 of the keyboard is pressed. The signal line SI is coupled to the signal line 28 for the control terminal of the on-off control latch 27 through each resistor RI. Pressing any contact switch 21 generates an on command signal 24 along signal line 28 during the time the contact switch is pressed. The base current flows into the PNP transistor Q4 and the on-off transistor Q3 of the latch 27. Base current from transistor Q3 flows into the emitter path to the collector of transistor Q4 and into the base of NPN transistor Q5 of latch 27, which regenerates the latch on or off. Has its collector connected to the base of transistor Q4. The base current from transistor Q3 functions like the sustain current or sustain current of latch 27.

)에 결합된다. 마이크로프로세서(25)에 전력이 공급되어진 후에, 마이크로프로세서의 프로그래밍은 도면에서 도시된 출력포트(D3)가 개방 드레인 인터페이스회로(OF)에 의해 하이상태로 스위치되는 것과 같은 것이다. 출력포트(D3)는 트랜지스터(Q5)의 베이스에서 래치(27)의 제어단자에 결합되어진다.Due to the latch 27 holding the conducting state forward biased transistor Q3, the voltage Vs of the battery is applied to the Vcc terminal to power the microprocessor 25. The Vcc terminal is coupled to the capacitor 29 and the reset-bar (BAR) input port of the microprocessor 25 (

) Is combined. After power is supplied to the microprocessor 25, the programming of the microprocessor is such that the output port D3 shown in the figure is switched high by the open drain interface circuit OF. Output port D3 is coupled to the control terminal of latch 27 at the base of transistor Q5.

As soon as the command signal is completely transmitted, the microprocessor 25 grounds the output port D3 by switching the output state of the port D3 to a low state by conduction of the incremental mode MOS transistor in the output interface circuit OF. . When the output port D3 is grounded, the latch sustain current and the main portion flowing in the path between the emitters in the collector of the transistor Q4 and the main part are transferred to the base of the transistor Q5 through the MOS transistor of the port D3 and the interface circuit OF. Is switched.

The generation of this alternative current path for the latch holding current bypassing the base of transistor Q5 initiates regeneration deactivation of the latch and turns off transistors Q4 and Q5. The ground path for the base current in transistor Q3 is disabled by inactivation of latch 27 to block conduction of on-off switching transistor Q3. The battery 23 is disconnected at the Vcc voltage supply terminal of the microprocessor 25. The capacitor 29 is discharged to the Vcc terminal and the R input port. The microprocessor 25 is powered off as the voltage is attenuated at the Vcc terminal.

In the device of the present invention just described, the amount of latch holding current is equal to the amount of base current which is a relatively small amount of transistor Q3. Therefore, the output port D3 of the microprocessor 25 must sink only a relatively small amount of current to initiate a continuous case of disconnecting the battery 23 from the Vcc power supply terminal.

Once the latch 27 is deactivated and Q3 becomes nonconductive, the relatively slow decay of the supply voltage at the Vcc terminal does not have the adverse effect of reliably holding the disconnected battery 23 from the Vcc supply terminal during the decay interval. Although the characteristics of the output port D3, such as the ability to sink current to ground, do not guarantee when the voltage at terminal Vcc is reduced below a certain minimum value, the MOS interface transistors from conduction to open drain As the voltage is attenuated at the supply terminal Vcc as the state change, any state change at the output port D3 may not accidentally turn on the transistor Q3. The result is that latch 27 has already been turned off reoccurring.

Claims (5)

A switch Q3 having a main current path coupled between a supply voltage source 23 and a voltage supply terminal Vcc of the digital controller 25 and a control terminal connected to an output of the latch 27, and the latch ( A set input of 27 and a key 20 coupled to the digital controller 25, an output D3 of the digital controller 25 coupled to a reset input of the latch 27, and to the supply voltage source. 25. An on-off device for a digital controller having said latch 27 having a first terminal connected thereto and a second terminal connected to a reference board, wherein said latch input is activated at said reset input of said latch 27. In response to the signal, the latch causes a current not to flow between the first and second terminals of the latch 27, and the output D3 of the digital controller 25 shunts the latch portion. Output d3 to stop current flow between the latches 27 by On-off device for digital controller (25) characterized by providing an alternative current path via. The set input according to claim 1, wherein the latch (27) has a first transistor (Q4) and a second transistor (Q5) for coupling the base to the collectors of different transistors, respectively, so that the set input is connected to the first transistor (Q4). Is coupled to the base of the second transistor (Q5), and the output of the latch (27) is coupled to the emitter of the first transistor (Q4). On-off device for digital controller 25. 3. The digital controller according to claim 2, wherein said output (D3) of said digital controller (25) comprises a MOS transistor and a reference potential (GND) point composed of an open drain coupled to said output port (D3). On-off device for 25. The on-off device for a digital controller (25) according to claim 1, wherein said switch (Q3) comprises a transistor. The signal port (SK) of the digital controller (25) generates a coded output signal, and a signal converter (CR) responsive to the coded output signal provides a signal representing the coded output signal. An on-off device for a digital controller, characterized by transmitting to a receiving device.

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