FR2538574A1 - MICROPROCESSOR CONTROLLED REMOTE EMITTER ON-OFF DEVICE FOR HOME APPLIANCE - Google Patents

Abstract

In an electric battery transmitter 10 controlled by a microprocessor 25 and intended for a home appliance, the collector current path of an on-off PNP transistor Q4 is connected between the battery 23 and a supply terminal Vcc of the microprocessor. . To ensure the power supply to the microprocessor, a switch 21 of the keyboard of the transmitter is pressed in order to ground the base of the on-off transistor and to make this transistor conductive. An NPN transistor Q5 forms a locking device that keeps the transistor on and off. Once the transmission of instruction signals has been completed, the microprocessor connects an output element D3 to earth. This output element is connected to the base of the NPN transistor Q5 and shifts the current therefrom so as to start the regenerative deactivation of the locking device. This deactivation interrupts the conduction of the on-off transistor. The microprocessor power supply terminal is then disconnected from battery 23. (CF DRAWING IN BOPI)

Description

The present invention relates to a walking device

  stop for a digital controller, for example a microprocessor, which controls the operation of a transmitter

distance for domestic appliance.

  The remote transmitter of a domestic device, such as a color television receiver or

  video disc, runs on electric battery, and its function-

  The ECU is powered by a microprocessor. In order to save the charge of the electric battery, the remote transmitter is only operated during the intervals when an instruction signal for the remote reception circuit of the device is transmitted. product

by the issuer.

  In a typical keypad transmitter device, an electrically conductive contact sheet is connected to the electrical ground. Each of the keypad switches is placed above the contact sheet at a distance from it. Signal lines coming from input elements of the

  microprocessor are connected to the keyboard switches.

  When a keyboard switch corresponding to a particular function or instruction to be transmitted is depressed, the switch establishes an electrical connection with the ground contact sheet, so that the line or lines are grounded. signals connected to this switch The input element or elements of the microprocessor that are connected to the signal lines are grounded, indicating to the

  microprocessor that the instruction in question must be issued.

  To ensure the power supply of the micro-

  processor when any of the keyboard switches

  is pressed, each of the signal lines connected to the

  is also connected to the control terminal of a

  on-off transistor switch The collector-

  the emitter of the transistor is connected between the electric battery, producing for example an operating voltage of 6.3 volts, and the voltage supply terminal of the microprocessor When a signal line is grounded by the contact sheet, the control terminal of the on-off transistor switch is also grounded, which turns on the transistor and allows the power supply of the power supply terminal

  in voltage of the microprocessor by the battery.

  Once the instruction has been issued by the remote transmitter, it is desirable to interrupt the power supply of the microprocessor and the associated transmitter circuit to save the battery charge. -Even a power interruption instruction signal by performing, for example, an internal grounding

an output element.

  The operating characteristics of the microprocessor, for example the ability of an output element to absorb current, can become unpredictable when the voltage at the power supply drops below a given value, for example

example below 4.5 volts.

  A particular feature of the invention is a provision

  locking device which ensures a reliable shutdown of the microprocessor by reliably maintaining an on-off transistor in a cut-off state for the entire period during which the

  supply voltage is going down to zero volts.

  The microprocessor stop instruction is applied to a control terminal of the interlock device and the input signal lines of the keyboard switches are connected to another control terminal of the interlock device.

  power supply terminal of the power supply device sector.

  rust is coupled to the control terminal of the switch to

transistor on-off.

  Grounding an input signal line activates the latching device and also allows the base current to flow to turn on the on-off transistor switch. A shutdown command signal from the microprocessor disables. the latching device, which prevents the base current from flowing in the on-off transistor switch to interrupt the power supply of the microprocessor With this interlocking control device, the charge of the battery is saved since the battery 'is connected to the voltage supply terminal of the

  microprocessor only during the production of an instruction signal.

  In addition, automatic shutdown, or automatic power shutdown, reliable microprocessor is assured as soon as the stop instruction signal is produced.

  The following description, designed as an illustration

  of the invention, aims to give a better understanding of its features and advantages; it is based on the single figure, which shows a remote control transmitter for home appliance comprising the on-off circuit constituting a

  embodiment of the invention.

  In the remote transmitter 10 controlled by micro-

  processor, which operates on battery, which can be seen in the single figure, each contact switch 21 of a keyboard assembly 20 is connected to one or more signal lines SI connecting the contact switches to several elements of As an example, only four lines of signals and input elements are shown in the single figure. In practice, it can be provided from ten to twenty lines of signals and elements of a digital control microprocessor. The microprocessor 25 may be the "COP 42 OL" model manufactured by National Semiconductor Corporation of Canada.

United States of America.

  The keyboard assembly 20 includes an electrically conductive contact sheet 22 that is electrically connected to the ground terminal of the remote transmitter circuit. Alternatively, the contact sheet 22 may be made of a plastic sheet. non-conductive material on which electrically conductive lines are printed which are connected to earth The contact sheet 22 is disposed below each contact switch 21, at a distance therefrom The fact of pressing a contact switch ground the associated signal line (s) and, therefore,

  ground the corresponding input element or elements.

  To transmit a particular instruction signal, for example a "channel scan" instruction signal for sequential channel selection when the remote transmitter is part of a remote control television receiver, or

  example, a "read" or "pause" instruction signal serving

  respectively to reproduction or to stop and start, when the remote transmitter is part of a disk drive

  or remote-controlled video tape, the user presses the

  appropriate contactor 21 which corresponds to the instruc-

  to be transmitted The corresponding signal line (s) IF are grounded, which puts the input element or elements

IN corresponding to the earth.

  The microprocessor 25 interrogates the switching states of the input elements IN. When it determines that a particular combination of input elements is in the low state, or grounding, the microprocessor 25 produces on an output element SK a serial train of coded pulses corresponding to the instruction selected by the user These pulses are applied to the emitter portion 26 of the transmitter 10 When the output element SK is in the state below, the element is grounded via the conductive source-drain path of a MOS transistor belonging to the output interface circuit which is associated with the element, and is not shown in the single FIG. therefore, transistors Q1 and Q2 are put into the cutoff state,

  which prevents a current from circulating in electrolysis diodes

  When the output element SK is in the high state, the transistor QI becomes conductive, which turns on the transistor Q 2 and allows a current to flow in the light-emitting diodes CR In this way, the coded pulses present on the SK terminal, which represent an instruction

  given, are transformed by the transducers of the diodes

  luminescent pulses in coded light pulses to be received

by the remote receiver.

  The power supply-of the transmitter 10 is obtained via an electric battery 23 The power supply is applied via the main current-conducting collector-emitter path of a PNP switching transistor Q 3. stop The collector of the transistor Q 3 is coupled to the base of the transistor Q1 in order to control the excitation of the part

  The collector of the transistor Q 3 is also

  connected to the voltage supply terminal V which supplies the

  In the unpowered state of the emitter 10, the transistor Q 3 is non-conductive,

  which has the effect of disconnecting the battery 23 from the microproces-

  25 and the control terminal of the transmitting part 26.

  No notable energy is drawn from the battery 23 in the state

disconnected power supply.

  The transmitter 10 is powered when a contact switch 21 of the keyboard is depressed The signal lines S1 are coupled via respective resistors R1 to a signal line 28 itself connected to a control terminal of a locking device The fact of pressing any one of the contact switches 21 produces a signal

  24 instruction on the signal line 28 that is as long as

  time the switch the contact is pressed Currents of

  base begin to flow in a PNP transistor Q 4 of the

  locking device 27 and in the transistor Q 3 of step

  stop The base current of the transistor Q 3 passes in the collector-emitter path of the transistor Q 4, then in the base of an NPN transistor Q 5 of the locking device 27, which transistor is connected by its collector to the base of the transistor Q 4 so as to make the locking device conductive or regeneratively activated The basic current of the transistor

  Q 3 acts as a maintenance or maintenance current

locking device 27.

  Since the latching device 27 holds the conduction-biased transistor Q 3 in the forward direction, the voltage V of the battery is applied to the terminal V so as to power the microprocessor. The terminal V is coupled thereto.

  a capacitor 29 and an input element "reposition bar

  Once the microprocessor power supply 25 has been completed, the programming of the microprocessor is such that an output element D 3 is switched up by the open drain interface circuit OF. shown in the single figure The output port M 3 is coupled to a control terminal of the locking device 27 at the base of the transistor Q 5. When the instruction signal is terminated, the microprocessor 25 switches the output element D 3 in the low state by means of the conduction of the mode-enriching MOS transistor of the output interface circuit OF, which earths the output element D 3 Once the grounded output element D 3, the main part of the maintenance current of

  the locking element which circulates in the collecting path

  emitter of transistor Q 4 is spaced from the base of transistor Q 5

  via the element D 3 and the transistor} OS of the interface circuit OF.

  The creation of this other path for the holding current of the locking device, which derives the base of the

  transistor Q 5, starts the regenerative deactivation of the

  The path leading to earth the base current of the transistor Q 3 is invalidated by the deactivation of the locking device 27, which interrupts the conduction of the transistor Q 3 of the transistor Q 3 and Q 5. on-off switching The battery 23 is disconnected from the voltage supply terminal V of the microprocessor 25 The capacitor DC 29 discharges into the terminal V and the input element R The microprocessor 25 ceases to be powered when the voltage

  present on terminal Vcc weakens.

  In the above-described device of the invention, the intensity of the latching holding current is simply

  that of the relatively small base current of the transistor Q 3.

  The output element D 3 of the microprocessor 25 must therefore absorb a current of relatively small intensity to start the sequence of events that disconnects the battery 23 from the voltage supply terminal V cc As soon as the device 27 is disabled and the transistor Q 3 becomes non-conductive, the relatively slow loss of the supply voltage present on the terminal V has no detrimental effect on the reliable maintenance of the battery 23 in the state disconnected from the power supply terminal Qn V during the DC voltage drop interval While the characteristics of the output element D 3, such as the ability to absorb current through the earth, can not be assured when the voltage present on the terminal V cc decreases below a certain minimum value, any change of state in the output element D 3 when the voltage present

  the power supply terminal VC is weakened, for example a change in

  state of the MOS transistor transistor between the conductive state and the drain state in open circuit, can not erroneously bring the transistor Q 3 to the conductive state. This results from the fact that the locking device has already been made non-conductive

in a regenerative way.

  Of course, those skilled in the art will be able to imagine

  from the device whose description has just been given

  merely illustrative and in no way limitative, various

  variants and modifications that do not depart from the scope of the invention.

Claims (5)

R E V E N D I C A T IO N S   An on-off device for a digital controller (25), comprising: a voltage supply terminal (V cc) of said digital controller for providing electrical power thereto; a source (23) of supply voltage; a first switch (Q 3) whose main current path is coupled between said voltage supply terminal and said supply voltage source, the conduction of the main current path being controlled by a control terminal said switch; - characterized by   means (Q 4, Q 5) which forms a locking device   the regenerative stage (27) and is coupled to the control terminal of said first switch so as to maintain said main current path conductive as soon as the locking device (27) has been activated; means (20, RI, 28) coupled to the control terminal of said first switch for applying a gait signal (24) thereto to initiate current conduction through said main current path and thereby supplying power to said digital controller (25), the locking device being activated at the time of application of said operating signal; and an output member (D 3) of said digital member, which is coupled to the locking device to provide another   path for the current which derives at least a part of the said   locking device, in order to start the regenerative deactivation thereof in order to interrupt the conduction of the main current path to interrupt the supply of said digital organ.   2 Device according to claim 1, characterized in that said means forming a locking device comprises a second switch (Q 5) having a main current path and a control terminal for controlling its conduction, and comprising a source (resistors 303 k and 10 k A 2) of   bias voltage coupled to said second switch (Q 5).   3 Device according to claim 2, characterized in that said output element (D 3) is coupled to the control terminal of said second switch and in that it comprises an interface circuit (MOS transistor) of said digital control member coupled to the output member (D 3) so as to derive   the current from said control terminal of said second component   mutator to disable the locking device (27).   4 Device according to claim 3, characterized in that said interface circuit comprises an open-circuit drain MOS transistor which is coupled to the output element (D 3)   and at a point of reference potential (the earth).   Apparatus according to claim 4, characterized by a signal output element (COO, CK 1) of said digital element for producing an encoded output signal, and a signal transducer which responds to said encoded output signal by transmitting, destination of a receiver unit, a signal representing coded output signal.