CA1256500A

CA1256500A - Universal remote control unit

Info

Publication number: CA1256500A
Application number: CA000510224A
Authority: CA
Inventors: Robin B. Rumbolt; William R. Mcintyre
Original assignee: North American Philips Consumer Electronics Corp
Current assignee: Philips North America LLC
Priority date: 1985-05-30
Filing date: 1986-05-28
Publication date: 1989-06-27
Also published as: JPH0710115B2; DE3687717D1; JPS6223700A; EP0203668A3; DE3687717T2; AU5791686A; AU592991B2; EP0203668B1; US4774511A; EP0203668A2; HK159695A

Abstract

Abstract:
Universal remote control unit.

The remote control unit has a selection mechanism for selecting any one of a number of categories of equipment to be controlled. The commands available for keyboard input in any given category are automatically displayed to the user upon selection of the category. Switches are provided for user selection of the model number of any one of a number of manufacturers of the equipment within the category to be controlled. Operation of the switches allows program controlled read-outs of formats stored in memory. An infrared LED is then energized in accordance with the format to transmit the signal to the unit to be controlled.

Description

~2~
PHA 40.484 1 01.04.19~6 Universal remote control unit.

1. Field of the Invention The present invention relates to remote control units and, particularly, to remote control lmits for controlling home appliances to carry out selected operations.
s ~ackaround of the Invention At present, many home appliances are available which can be remotely controlled by the user. For example, a television set can be turned on and off, a channel can be selectedr a video cassette recorder controlled to play or record, etc. However, each manufacturer uses a different signal format to effect his control. Not only do different operations require different control signals, but the basic format, such as the bit timing, the number of bits per ~ord, the width of the pulses, the modulating frequency, if any, applied to each pulse, the presence of, length of, and format of start, lead, or trailer pulses and the number of correct receptions of a particular command required to activate the appliance to carry out the sele~ted operation varies from manufacturer to manufacturer. The basic format may also be different for different model numbers of the same manufacturer.
Many homes have appliances which can be remotely controlled, but which are manufactured by different manufacturers.
Further, control of, for example, a video cassette recorder frequently requires the ability to control a related appliance, e.g. a television set, in conjunction therewith. At present, viewing a recorded program requires use of two individual remote control units, particularly if the recorder and the television set are not made by the same manufacturer.

Summary of the Invention It is an object of the present invention to furnish a universal remote control unit which allows control of different types of appliances as we:Ll as appliances manufactured by different manufacturers.

~. ~

2 20104-8054 The remote control unit is to be simple to operate, light, reliable, and relatively inexpensive.
In accordance with the invention, the user selects a particular category of appliance and its model number andJor manufacturer. Selecting the category automatically causes a display of commands available in the category, again for user selection. After the relevant selections have been made, the selection elements are automatically scanned under control of a microprocessor and an address signal is genera~ed. This address signal allows readout from a storage of a product code signifying the required parameters, i.e. frequency, pulse width, pulse repetition rate, word length, etc. and the application of product code signals to a formatter unit. The latter energizes a transmitter section which transmits slgnals corresponding there~o to the controlled appliance, thereby causing the appllance to execute the command selected by the user.
According to the invention, use of the remote control unit can further be facilitated by permanent association of operation commands of one appliance with related opera~ion commands of another. Thus, in a preferred embodiment, user selection of a VCR "play" command will automatically trigger the command switchlng the associated television set to the empty channel to be used for display, followed by the command setting the VCR to the "play" mode. This concept is referred to as command chaining herein.
In a further preferred embodiment, the user selectable operation commancls ~or some appliance categorles al~o automatically include commands associated with a related category.

~a 20104-805 For example, television volume controls are available upon selection of the VCR ca~egory.
In accordance with a broad aspect of the invention there is. provided a unit for remotely controlling a plurality of appliances each belon~ing to a one of a plurality of categories, each having a model number signifying a given model of a given manufacturer, each adapted to carry out a predetermined function upon receipt of a remote control signal having a predetermined format, comprising.
transmitter means for transmitting remote con~rol signals having formats corresponding to transmit control signals applied thereto;
first user-operable selector means for generating a first selector signal signifying the selected one of said plurality of model numbers;
second usex-operable selec~or means for generating a second selec~or signal signifying the user-selected one of said appliance categories;
command display and selec~ means for displaying user selectable commands associated with the selected one of said appliance categorles, and for generating a command signal signifylng one of said commands in response to user's selection thereof;
means for scanning said fist and second user-operable selector means and said command and select means and generating an address signal corresponding to the user selected category, model number and operal;ion command;
memory means storing a plurality of command tables in ~6~
2b individually addressable storage locations;
and a readout means for receiv:Lng said a~dress siynal and reading out command table data in said storage locations under control thereof, and applying the so-read out command data to said transmitter mean~, whereby said transmitter means transmits a remote control signal having the co:rrec~ format to control the user-selected appliance to perform the user-selected operation.
In accordance with another broad aspect of the invention there is provided apparatus for remotely controlling a first and a second appliance respectively responsive to command signals having a first format and a second format different from said first format, comprising memory means for storing format defining data for each of said appliances in addressable memory locations;
user controllable means for selectively addressing said memory locations and reading out said format defining data stored therein;
user controllable means for generatlng command signals signifying a desired operation of said appliance;
means connected to said command signal generating means and said memory means for formatting said command signal in accordance with said read out format defining data, thereby creating a formatted command signal; and transmitting means connected to said formatted command signalling generating means for transmitting said signals to said appliance to be controlled.
The present invention, as well as additional obje~ts thereof, will be better understood upon reference to the following ~2~D6S0 0 20104-8054 2c description taken in connection with the accompanying drawing.
Brief descriPtion of_ he drawin~
Figure 1 is a bloc~ diagram of the remote control unit according to the present invention;
Figure 2 is a schematic diagram of the stand-by circuit;
Figure 3 is a flow chart for the microprocessor of ~ ~D~ ~
PHA 40.434 3 01.04.1986 Figure 1;
Figure 4 is a schematic diagram illustrating the keyboard mechanism of the present invention, and Figure 5 is a schematic diagram of an in~rared drive circuit.

Descrivtion of the Preferred em~odiments In the schematic diagra~ of Figure 1, a microprocessor which is the central control unit for the system is denoted by reference numeral 10. The timing of microprocessor 10 is controlled by crystal time base 12. The basic microprocessor function is to receive data from three user-controlled selecting devices and to energize an infrared transmitting system to transmit signals with a format selected in accordance with this infcrmation. The transmitted infrared radiation is then received by the appliance and causes it to operate as desired by the user.
In the preferred embodiment, the microprocessor is Hitachi HD6301 operated in mode 6 with an Gscillator frequency of 4 ~Hz and an instruction cycle time of 1 microsecond. This speed is necessary in order to generate the carrier output frequencies of up to 55 KHz required by some IR control systems.
The first of the user-operated selection devices is a category selector switch 14, by which the user selects the category of the appliance which is to be controlled. Its output is connected to microprocessor 10 through five lines 16. In the example illustrated in Figure 1, the following categories are provided: a television receiver (TV), a video cassette recorder tVCR) a disc player (disc), an audio system (audio), and an auxiliary input (aux) suitable, for example, for controlling a cable converter.
The second selection device is a keyboard 18. As will be described in greater detail with reference to ~igure 4, category selector switch 14 is mechanically coupled to an escutcheon slider which moves in conjunction with the movement of the category selection switch to "illuminate" :legends indicating specific comm~nds associated with the selected categories in display windows or areas 20. Additional areas indicated by dashed lines and designated by reference numbers 20a display operation commands available for controlling an appliance PHA 40.484 4 01.04.1986 operationally associated with the appliance of the category selected by selector switch 14. For exa~ple, a television receiver is operationally associated with a video cassette recorder when the latter is in the "play" mode.
In the preferred e~bodiment, keyboard 18 is a 3x11 matrix, addressable by 11 address lines of a bus 22. Pus 22 is constituted by an eight ~ine bus 24 activated by an address latch 26 and a four line bus 28 activated by microprocessor 10. Keyboard output i9 furnished on a three line bus 29.
Finally, two sets of dip switches, 30A and 30~, allow the user to identify the model number and/or manufacturer of the appliance to be controlled. The switches are addressed by a twelve line bus 30 also connected by busses 24 and 28.
Within each category, a number of appliance models is individually selectable in accordance with the following table which, however, is illustrative only:

Table I
1) TV up to 64 for~ats (6 dipswitches) 2) VCR up to 8 formats (3 dipswitches)

3) DISC up to 4 formats (2 dipswitches)

4) AUDIO up to 8 formats (3 dipswitches)

5) AUX up to 4 formats (2 dipswitches) 25 88 formats 16 dipswitches Also shown in Figure 1 is an electrically programmable read only memory (EPROM) 32. This memory contains look-up tables indexed by the category selector, the dipswitches, and the particular key pressed on the keyboard. Indexing takes place via addresses on a twelve line address bus 34 si~ilar to bus 22. The data read out from the tables, including a product code and a command code, is then passed to the appropriate IR transmitter routine called a "formatter" also stored in EPROM 32. Each formatter is a device-specific program designed to generate the precise carrier frequency, pulse width, pulse modulation and overall timins format required by the particular device. EPROM 32 is also controlled by an address decoder 36 through a "selector" line and ~L~56~
PHA 40.484 5 01.04.19a6 an ~output enable" line. The output of EPROM 32 is furnishe~ on an eight line data bus 38 which connects to a bidirectional bus lines 42. Bus 42 interconnects microprocessor 10, address latch 26 and a tri-state buffer 44.
The input to address decoder 36 is a 4 bit address furnished by four lines from microprocessor 10. A latch enable line connects microprocessor 10 to address latch 26. Address decoder 24 also has an output connected via an Uenable'' line to buffer 44.
The data output lines from keyboard 18 are also connected to the inputs of a stand-by controller 46. A first and a second output of stand-by controller ~6 is connected to a reset and stand-by input of microprocessor 10, respectively.
Finally, an output port 38 of microprocessor 10 is connected to IR driver circu.it 40 which in turn drives infrared light emitting diodes (LED's) ~2a.
Address latch 26, when enabled, latches the address applied to it via bus 42 so that the latter may be used to transmit data to microprocessor 10.
Stand-by circuit 46 is shown in greater detail in Figure 2, wherein corresponding elements have the same reference numerals as in Figure 1. Specifically, it consists of an OR gate ~10 having a three line input from bus 29. A timing circuit consisting of a resistor 512 and a capacitor 514 is connected to the output of OR gate 510. The common point of resistor 512 and capacitor 514 is connected to one input of an OR gate 516 whose second input is connected to a latch output o~
microprocessor 10. The output of OR gate 516 is connected to the reset and stand-by terminals of microprocessor 10.
Operation of the above-described equipment will now be described with reference to the flow chart of Figures 3A-D.
Referring to Figure 3A, upon inserion of the battery, microprocessor initialization takes place. A random access memory (RAM) in the microprocessor, the input-output ports, and a flag in the internal memory of the microprocessor are set to initial conditions. The microprocessor then enters the sleep mode. In this mode, stand-by circuit 46 grounds the reset and stand-by pins of the microprocessor. A
circuit internal to the microprocessor shuts down all internal circuitry except for memory and the circuitry monitoring the "stand-by" and ~i6~

P~IA 40.484 6 01.04.1986 "reset" lines. This state continues until a key of keyboard 18 is pressed.
Upon pressing of a key, OR circuit 510 receives an input, causing it to generate an output, charging capacitor 514. This, in turn, causes an output to appear at OR gate 516, energizing the Creset'' and rstand-by~ circuits in the microprocessor, and also energizing the output enable of latch 26. Monitoring of the stand-by and reset lines as well as the previously set flag causes the microprocessor to energize the latch for stand-by circuit 46 and to enable address latch 26.
The microprocessor then executes the keyboard scan.
Specifically, the eleven rows of keyboard 1~ and interrogated by bus 22 in a predetermined sequence. If a key on keyboard 18 is pressed, one of these rows is connected to its column, causing one of the lines of bus 29 to be at a high level at a specific step in the program. Buffer 44 is enabled by address decoder 36 to allow the information from keyboard 18 to be passed onto microprocessor 10.
The microprocessor then enters the subroutine shown in Figure 3B to determine which key (or keys) ~as pressed. Specifically, it is first determined whether the number of keys pressed is equal to 1 or greater than 1. If the number is greater than 1, it is determined whether the number is equal to 2. If the number is not equal to 2, i.e.
if more than 2 keys have been pressed an unacceptable condition prevails and the program is aborted, a new scanning of the keyboard being initiated.
If two keys had been pressed, it is determined whether these are the record and play keys. It must be reme~bered that to activate the VCR to "record" both of these keys must be pressed. The category switch is then interrogated. This is an internal interrogation, since the outputs of switch 14 have been applied to the microprocessor.
If the category is not either VCR or audio tape, the program is again aborted with resumption of keyboard scan. Howe~er, if the category switch does read either YCR or audio tape, the keyboard co~mand i5 interpreted as a record command. Referring again to Figure 3A, the keyboard position number o~ the pressed key is then stored in an an internal random access memory (RAM) in the microprocessor. On the other hand, i~ the nll~ber of keys pressed is equal to 1 and the so-pressed key is the record key, the program aborts as mentioned above. If it is not ~s~
PHA 40.484 7 01.04.1986 the record key and not the play key, the main program is resumed and the keyboard position number of the pressed key is stored in internal RA~.
If it is the play key, the category switch is scanned. If the category is a category other than the VCR, the keyboard position number is again stored.
If, however, the category is YCR, the command chain illustrated in Figure 3C commences. First, the category number in the RAM is set to the number signifying Ntelevision". ~he dipswitches are then scanned in the same manner as described previously with respect to the keyboard scan. Data readout on bus 31 is applied ko the microprocessor through bus 42, latch 26 aqain carrying out its latching function. The dipswit~h data is stored in RAM.
At this point, the microprocessor sends signals to the IR
driver 40 causing it to send a command to the TV to switch it to the output channel of the VCR, e.g. channel 3. First, the key data in the RAM is set to zero. The "send" function is then executed. This is described in subroutine A, Figure 3D, which will be discussed in detail below.
After the command "O" has been sent, the key data in the RAM is set to "3". The send function is again executed. At the end of this particular send operation, the television has been switched to channel 3.
At this point, the category number in RAM is set to the VCR value. The key data is sek to N play".
The system then returns to the main program illustrated in Figure 3A. The category switch is scanned and the result of the scan is stored in internal RAM. The scanning is controlled by a program in internal ROM. After the category switch data has been entered into RAM, the dipswitches are scanned, also under control of a pxogram in internal ROM. The result of the scan is stored in the RAM of the microprocessor.
At this point, the microprocessor RAM contains data specifying the manufacture and model number of the device being controlled, the type of device it is and the key data, i.e. the data indicating the desired command.
The program then goes into the Nsend" mode illustrated in Figure 3D.
The program enters a "decode" routine located in internal PHA 40.48~ 8 01.04.1986 ROM. The stored category switch data, key data and dipswitch data is used to calculate the address of the command table in EPROM 32. The command table stores the following data for each associated key:
~. the command word bit pattern;
2. the formatter starting address;
3. the associated category type; and 4. a repeating or nonrepeating flag, i.e. a flag signifying whether or not the command is to continue to be transmitted until the key is no longer depressed.
The category type found in the table is then checked against the currently selected category. A test is carried out whether they match. If not, the category data in RA~ is replaced with the category data found in the table. For example, if the selected category is either disc or VCR, a TV command such as ~volume up~ will cause the ~television~ category to be stored in RAM.
If the two categories do match, the program jumps to the formatter starting address. The IR code is sent to the IR driver, i.e., the microprocessor acts in response to formatter instruction stored in EPROM to send the proper carrier frequency, type of code, timing, etc.
to the IR driver. The keyboard is then scanned again. If the key is no longer pressed, the stand-by circuit is unlatched. If the same key is still pressed, a test is carried out as to whether the repeat flag is on If the repeat flag is not on, no code is output; however, keyboard scan continues until the key is released. If the repeat flag is not on, the program loops back to the formatter starting address so that the IR
code continues to be sent to the IR driver.
It should be noted that after the stand-by circuit is unlatched by microprocessor 10, the timing circuit consisting of resistor 512 and capacitor 514 of Figure 2 continues to hold the output of OR gate 516high for a relatively short time since only a high impedance discharge path is available for the capacitor. Alternatively, latching and unlatching of the microprocessor control could be dispensed with, a timing circuit being provided which maintains the microprocessor in stand-by for a time period adequate to assure that the command has been carried out. For greater reliability, and because of the presence of chain commands, i.e. an automatic command sequence initiated for depression of a single button, a positive latch and unlatch by the ~2~

PEIA 40.484 9 01.04.1986 microprocessor is preferable.
Referring now to Figure 4, the construction of the keyboard-category selector switch combination will be described in detail. An opaque keya~oard cover 410 has translucent areas 412, 414 formed in the shape of letters or labels. One ox more label is associated with each button or key. In the illustration, the labels associated with a button 416 are ~onU and ~off". In operation, the keyboard cover is positioned parallel to and in close proximity of the sliding escutcheon 418. The slider mechani~m which moves the escutcheon relative to the opaque top layer of the keyboard is operated by a thumb wheel 420. The sliding escutcheon carries a first and second contrasting color, i.e. contxasting to the color of the top layer, and, inbetween the two contrasting colors, a color which is the same as that of the top layer. In the position illustrated, the first contrasting color is underneath the "off" label. This label would thus be "lit".
Thumbwheel mechanism 420 is activated by the user to select the category of appliance to be controlled, i.e. thumbwheel 420 controls the position of category selector switch 14 of ~igure 1. The same button can thus be used for different commands, depending upon the selected category. For example, pressing a given button may turn a VCR
off, or turn a televislon set on.
The IR driver circuit illustrated in Figure 5 is a :` standard driver circuit illustrated ~e~ for completeness only. It consists of a first ampllfier stage including a transistor 610 having an emitter resistor 620 and a collector resistor 630. Three diodes 640 are connected in parallel with resistor 630. The collector of transistor 610 is connected to the base of a second transistor 650 connected as an emitter follower. Two light emitting diodes 660 are connected in the emitter circuit of transistor 650. The light emitting diodes emit infrared radiation under control of signals applied to the base circuit of transistor 610 by microprocessor 10.
Alt~ough the invention has been illustrated in a particular prefexred embodiment, it is not intended to be limited thereto. Many vaxiations in operation and constr~ction will readily occur to one ski:Lled in the art and are intended to be encompassed in the invention as set forth in the following claims.

PHA 40.484 10 01.04.1986 APPendix to Fiqures 3A, 3B. 3C, 3D
Reference number Inscription 300 insert battery 5 301 ~p initializes set flag 302 enter sleep mode 303 standby circuit checks for any keyboard key pressed 304 any key pressed 10 305 standby circuit activates "reset" and "standby"
lines on ~p. ~p reinitializes 306 ~p executes keyboard scan program in internal ROM
307 determine which key(s) was pressed 15 308 store keyboard position number of key pressed in internal RAM
309 read category switch stoxe result in internal RAM
310 read dipswitch store result in internal RAM
20 311 multi key patch (Figure 3B) 312 # of keys pressed 313 # = 2?
314 are they record + play?
315 read category switch 25 316 category = VCR or audio tape?
317 set keyboard data = record 318 is it record key?
319 is it play?
320 read category switch 30 321 category = VCR?
322 set category number in RAM = TV value 323 read dipswitch t store in RAM
324 set key data = "0"
325 execute "send" functions 35 326 set key data = ,,3u 327 execute "send~ functions 328 set category number in RAM = VCR value ,

6~0~

PHA 40.484 11 01.04.1986 329 set key data = ~play"
330 using stored category switch data and dipswitch data calculate address of co~mand table in external EPROM
5 331 using command table address and key position numher ~et for~atter address and data out of command table 332 check currently selected category against category type found in table 10 333 do they match?
334 xeplace category data in RAM wlth category data found in table 335 jump to formatter starting address. Execute instructions to send IR code to IR driver 15 336 scan keyboard 337 same key still pressed?
338 unlatch standby circuit 339 repeat flag on?

Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE PROPERTY
OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. Unit for remotely controlling a plurality of appliances each belonging to a one-of a plurality of categories, each having a model number signifying a given model of a given manufacturer, each adapted to carry out a predetermined function upon receipt of a remote control signal having a predetermined format, comprising:
transmitter means for transmitting remote control signals having formats corresponding to transmit control signals applied thereto;
first user-operable selector means for generating a first selector signal signifying the selected one of said plurality of model numbers;
second user-operable selector means for generating a second selector signal signifying the user-selected one of said appliance categories;
command display and select means for displaying user selectable commands associated with the selected one of said appliance categories, and for generating a command signal signifying one of said commands in response to user's selection thereof;
means for scanning said first and second user-operable selector means and said command and select means and generating an address signal corresponding to the user selected category, model number and operation command;
memory means storing a plurality of command tables in individually addressable storage locations;
and a readout means for receiving said address signal and reading out command table data in said storage locations under control thereof, and applying the so-read out command data to said transmitter means, whereby said transmitter means transmits a remote control signal having the correct format to control the user-selected appliance to perform the user-selected operation.

2. A remote control unit as set forth in claim 1, wherein said command display and select means comprises an array of command display elements, and third means operable in dependence upon operation of said second user-operable selector means for displaying commands associated with the user-selected appliance category in corresponding ones of said command display elements.

3. A remote control unit as set forth in claim 2, wherein said command display and select means is a keyboard having a plurality of keys and at least a first and second command respectively associated with a first and second one of said categories associated with at least one of said keys;
wherein said command display element associated with said at least one of said keys comprises a first and second symbol respectively signifying said first and second command positioned in proximity of said button;
wherein said third means comprises a slider carrying means for making said first or said second symbol legible depending on the relative position of said slider means to said symbols; and wherein said third means comprises means coupled to said second user of operable selector means for moving said slider means in correspondence to movement of said second user-operable selector means.

4. A remote control unit as set forth in claim 3, wherein said second user-operable selector means comprises a rotary selector mechanism.

5. A remote control unit as set forth in claim 2, wherein said third means is mechanically coupled to said second user operable selector means.

6. A remote control unit as set forth in claim 1, wherein at least one additional command is associated with a predetermined one of said selected commands for transmission in a predetermined time relationship to the latter;
wherein said readout means is operative under control of program means; and wherein said program means automatically controls said readout means to read out command table data associated with said selected and said associated commands in said predetermined time relationship upon receipts of an address signal associated with said predetermined one of said commands.

7. A remote control unit as set forth in claim 6, wherein said at least one of said predetermined selected commands is a VCR
"play" command and said associated command is a TV channel switch command generated prior to said VCR "play" command.

8. A remote control unit as set forth in claim 1, wherein said user-selectable commands further comprise commands associated with an additional appliance category operationally associated with said selected one of said appliance categories.

9. A remote control unit as set forth in claim a, wherin said selected one of said appliance categories is the "VCR" category and said additional category is the "television" category, whereby user control of a television set can take place when said remote control unit is set for controlling a VCR.

10. Apparatus for remotely controlling a first and a second appliance respectively responsive to command signals having a first format and a second format different from said first format, comprising memory means for storing format defining data for each of said appliances in addressable memory locations;
user controllable means for selectively addressing said memory locations and reading out said format defining data stored therein;
user controllable means for generating command signals signifying a desired operation of said appliance;
means connected to said command signal generating means and said memory means for formatting said command signal in accordance with said read out format defining data, thereby creating a formatted command signal, and transmitting means connected to said formatted command signalling generating means for transmitting said signals to said appliance to be controlled.

11. A remote control unit as set forth in claim 10, wherein operation of said first appliance in response to a first command requires transmission of a second command to said second appliance;
further comprising means responsive to said first command signal for automatically generating said second command signal, formatting said second command signal and said first command signal in accordance with read out format defining data corresponding to said second and first appliance, respectively, and means for applying the so formatted first and second command signals to said transmitting means in a predetermined sequence for transmission to said first and second appliance, respectively.

12. A remote control unit as set forth in claim 11, wherein said first appliance is a video cassette recorder and said second appliance is a television receiver;
wherein said first command is a "play" command and said second command is a "switch to predetermined channel" command; and wherein said transmitting means to transmit said second command prior to transmission of said first command.