Miniature remote control system

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.

FIELD OF THE INVENTION

The present invention relates to radio frequency transmitters. More particularly, this invention provides a miniature transmitter that is small enough to fit within a cigarette lighter socket in an auto dashboard. This invention also provides a receiver which, when activated by the transmitter, is able to operate electrical appliances that are connected to the receiver.

BACKGROUND OF THE INVENTION

Remotely operated garage door openers are a widely used consumer accessory, and are commonly located and activated from a user's vehicle. These devices provide convenience, security and accessibility for many people who desire or require such a system. Remote operation of garage doors, security gates, lighting and alarms has become a necessity for many people.

Existing remote controllers for use in vehicles have had numerous problems associated with their functionality, reliability, security and their location within the vehicle. Common hand-held remote controllers are often bulky and difficult to use. Hand-held units are usually battery operated and commonly malfunction when the stored battery charge is low. Since vehicles are operated in many weather conditions, the available power from battery operated controllers is diminished in cold temperatures.

Hand-held units are also easily misplaced, either within the vehicle or by inadvertent removal from the vehicle. Looking for a misplaced remote controller can pose a safety problem in a moving vehicle. Hand-held remote controllers are also prone to damage, as they are commonly used at the same time the user is busy operating a motor vehicle. Previous attempts to provide a convenient means for control of remote systems from the auto dashboard have met with limited results.

In U.S. Pat. No. 4,286,262, Wahl discloses a system for opening garage doors in which a radio receiver in the garage, upon receipt of a signal, operates to open the garage door and in which a casing containing a radio transmitter is adapted for insertion into the socket of a cigarette lighter in the driver's compartment of a motor car. Wahl also discloses a radio transmitting device in which a casing containing a radio transmitter is insertable into a socket of any type at any location together with means for energizing the transmitter to emit a signal when the casing has been inserted in the socket, for whatever purpose the signal may be utilized.

In U.S. Pat. No. 3,967,133, Bokern teaches the construction and use of a relatively simple compact and portable device which makes power available at different desired voltages even at remote locations. Bokern also states that his device may include means which obviate the possibility of a polarity reversal or misconnection.

In U.S. Pat. No. 5,007,863, Xuan discloses a module-type multi-function power outlet adapter for use of add-on electrical accessories in an automotive vehicle having a cigarette lighter socket. This device embodies a plurality of separate detachable modules which may be attached to a basic module insertable into the lighter socket and constructed to receive the additional modules, so to provide multiple electrical outputs. A simple positioning pin structure ensures correct power leads connection and secures the combination between modules. The resulting solid structure allows easy reception for plug-in accessory equipment.

In U.S. Pat. No. 5,073,721, Terrill et al. disclose a noise immune electronic switch which is connectible between a cigarette lighter socket of a vehicle and a plug-in accessory device.

In U.S. Pat. No. 4,529,980, Liotine et al. Transmitter and receivers for controlling remote elements which use a synchronous serial transmission format and which allows changes in coding to be automatically made between the receiver and transmitter and wherein the code is stored in memories of the transmitter and receiver and wherein the receiver can generate and transmit a new code with a light emitting diode so as to change the code in the transmitter. The transmitter and the receiver use micro-computers which are suitably programmed and include non-volatile memories.

In U.S. Pat. No. 4,409,592, Hunt discloses a packet communication system employing a carrier sense multiple access protocol with detection, with an improved means of collision detection and with an improved means for managing access to a communication medium or channel.

In U.S. Pat. No. 4,988,992, Heitschel et al. disclose a system for establishing a code and controlling operation of equipment. The system includes a transceiver including a receiver for the signal generated by the first transmitter and memory for storing the code carried by that signal. The transceiver includes a second transmitter for transmitting a radio frequency signal carrying the code.

In U.S. Pat. No. 5,148,159, Clark et al. disclose a remote control system including one or more portable units and base unit which employs identification codes for security.

In U.S. Pat. No. 4,665,395, Van Ness discloses an automatic vehicular access control system for use by various government, business and private operations having a need to control the entrance of vehicles to their grounds or facilities.

In U.S. Pat. No. 4,912,463, Li discloses a remote control apparatus which has a transmitter which is capable of being switched between a normal position and a changing position, and a receiver which is capable of being switched between a normal mode and a changing mode.

In U.S. Pat. No. 4,827,520, Zeinstra discloses a voice actuated control system for controlling vehicle accessories.

In U.S. Pat. No. 4,771,399, Snowden et al. disclose a memory programming system which provides a method and apparatus for programming and reading an electronic device memory through its power source connections.

In U.S. Pat. No. 3,906,348, Wilmott discloses a serially transmitted code which can be detected by a receiver.

In U.S. Pat. No. 4,241,870, Marcus discloses a housing mounted between the visors in the headliner of a vehicle for receiving and supplying operating power to a remote transmitter used for opening garage doors.

Previous inventions, such as the device described in U.S. Pat. No. 4,241,870 by Marcus, have located the portable transmitter unit in a overhead location within the motor vehicle, picking up electrical power through a socket located in an overhead console. These units rely on carrier signal technologies, and require line-of-sight operation through the vehicle windshield. Marcus claims that by mounting the transmitter high in a console, the radio waves will exit through the windshield, thus providing the required line of sight operation. Marcus located the controller overhead, in the visor area of an automobile, which has met with minimal acceptance by both automobile manufacturers and consumers. These controller modules are unique to different vehicle models. They impair vision out the front of the vehicle, and cannot be applied to many models, such as convertibles. Special wiring extensions to supply power to these overhead consoles are also required, adding to the manufacturing cost of vehicles supplied with such systems.

Hand-held transmitter systems that require a specialized storage area within a vehicle tend to be inappropriate for the interior designs of most vehicle manufacturers. Most hand-held transmitters use carrier signals that require “line of site” operation through the vehicle windshield area. These transmitters use carrier signals with a small number of unique codes. This can pose a security risk when security gates and garage doors are opened inadvertently or deliberately by other transmitters that use the same carrier signal code.

U.S. Pat. No. 3,906,348, by Wilmott, provided further encoding and decoding for transmitter and receivers for digital radio control, but the hardware design is inappropriately expensive for integration into a consumer product.

Previous remote controllers have been used in motor vehicles to operate garage doors and similar devices. These existing remote controllers are typically large, awkward, and have proven to be difficult to integrate with modern automobile design. While large automobiles, such as Cadillacs™ and Lincolns™, may have enough room over the rear-view mirror, most cars do not have enough space for such large devices. Since most controller designs require line of sight operation, they are susceptible to interference. A significant number of existing remote controller designs fail to offer reasonable security for the user, due to a large number of users and a small number of unique codes. The development of a miniaturized, inexpensive remote controller that can be installed directly in an existing cigarette lighter enclosure, that can provide interference-free operation from a reasonable distance, while providing a large number of unique codes, would constitute a major technological advance. The enhanced performance that could be achieved using such an innovative device would constitute a major technical advance and satisfy a long felt need within the consumer marketplace.

SUMMARY OF THE INVENTION

The Miniature Remote Control System disclosed and claimed below overcomes the problems encountered by previous mobile remote control systems. The Miniature Remote Control System integrates a radio circuit in a small device that can fit inside a cigarette lighter enclosure in an automobile, truck, van, forklift or other vehicle. When activated, it can be used to open garage doors and security gates, activate or deactivate burglar alarms, turn on lights inside or outside the home, or activate other devices from a remote location.

The remote control transmits a coded serial pulse train to a receiver up to 200 feet away. The transmitter board fits inside a cigarette lighter housing and simply plugs into the existing lighter receptacle in a car. A miniature switch located on top of this housing is manually activated to transmit a unique code (one of 19,683) on a 380 MHz carrier frequency. The receiver processes the carrier signal, and extracts the serial code. The code is then compared to the preset code, and, if a match is found, a relay is triggered.

The innovative Miniature Remote Control System incorporates the latest remote control technology in a package that is small, safe, reliable, cost-effective, and appropriate for wide acceptance throughout the automotive industry. Installation of the present invention simply entails replacing a standard cigarette lighter with the a remote emitter, which is designed to fit within and operate from a standard lighter receptacle, which is supplied and conveniently located within all modern vehicles. The majority of people who drive vehicles do not smoke, allowing wide market acceptance of the use of the remote emitter located within the standard lighter receptacle. This invention will become the standard-bearer for remote control technology and constitutes a major step forward in the field of automotive accessory design.

An appreciation of other aims and objectives of the present invention and a more complete and comprehensive understanding of this invention may be achieved by studying the following description of a preferred embodiment and by referring to the accompanying drawings.

A BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is an illustration of the Miniature Remote Control System, using a cutaway view of a garage area of a building. This illustration shows how the present invention would be used to provide remote operation of a standard garage door opener mechanism.

FIG. 2

is a perspective assembly view of the remote emitter and a matching lighter receptacle into which the remote emitter would be installed.

FIG. 3

is an depiction showing the remote emitter installed within the interior of a vehicle. As the vehicle approaches a garage, the remote emitter is activated to send a carrier signal to open a garage door.

FIG. 4

offers a detailed view of a carrier signal being emitted from a vehicle equipped with the remote emitter, as the vehicle approaches the location of the remote receiver.

FIG. 5

is an alternative embodiment of the present invention, in which the remote receiver is an integral component of a garage door opener.

FIG. 6

is a plan view that illustrates some of the remote control applications for which the Miniature Remote Control System can be used.

FIG. 7

is a schematic of the remote emitter.

FIG. 8

is a schematic diagram of the remote receiver.

FIG. 9

is a schematic of the receiver power supply.

FIG. 10

is a depiction of the receiver board layout for the present invention.

FIG. 11

shows an embodiment of the second receiver board layout.

FIG. 12

shows a top view of a board design for a production transmitter.

FIG. 13

shows a side view of the production transmitter board.

FIG. 14

illustrates details the component side of the bare production transmitter board.

FIG. 15

provides a detailed view of the circuit side of the bare production design transmitter board.

FIG. 16

is a composite view of the production transmitter board.

FIG. 17

is a top view of the surface mount transmitter board embodiment.

FIG. 18

is a detailed plan view of the surface mount remote emitter assembly.

FIG. 19

is a detailed side view of the surface mount remote emitter assembly.

FIG. 20

provides a plan view of an alternate transmitter embodiment.

FIG. 21

is a side view of the alternate transmitter embodiment.

FIG. 22

shows the remote emitter designed to fit in the cigarette lighter receptacle of a Lincoln™ automobile.

FIG. 23

shows the remote emitter designed to be used in the cigarette lighter receptacle of a Mercedes Benz™.

FIG. 24

is an expanded view of an alternate embodiment of an extended remote emitter.

FIG. 25

shows an installed view of the extended remote emitter.

FIG. 26

reveals a block diagram of another alternate embodiment of the present invention, the Miniature Transceiver Control System.

FIG. 27

is a perspective illustration of the remote transceiver, as it would be installed in the console of a vehicle.

FIG. 28

is a block diagram of the power circuitry for the remote transceiver.

DETAILED DESCRIPTION OF PREFERRED & ALTERNATIVE EMBODIMENTS

System Overview

FIG. 1

is an illustration of the Miniature Remote Control System

10

, which shows a cutaway view of a garage area G. The Miniature Remote Control System

10

provides a miniature, radio frequency remote emitter

12

that is designed be installed within a vehicle V. The remote emitter

12

is used to operate an external device ED, such as a garage door opener GDO, that is connected to a remote receiver

14

. When activated, the remote emitter

12

transmits a 380 MHz coded serial pulse train

16

. At this frequency, the coded serial pulse train

16

can easily penetrate obstructions located between the remote emitter

12

and the remote receiver

14

, such as the vehicle V, the vehicle windshield W, the garage wall GW, and the garage door GD. In the claims, the term “carrier signal” encompasses any coded serial pulse trains

16

described in the specification.

The remote emitter

12

is able to transmit the serial pulse train

16

to the remote receiver

14

from a distance up to 200 feet away. When in range, the remote receiver

14

senses the incoming serial pulse train

16

through the receiver antenna

18

. The remote receiver

14

processes the coded signal pulse train

16

, and extracts the serial transmitter code

20

. The transmitter code

20

is then compared to the preset receiver code

22

. If the transmitter code

20

and the receiver code

22

are identical, the remote receiver

14

provides the logic necessary to provide power to operate an external device ED, such as the garage door opener GDO.

The remote receiver

14

is powered by a 16 volt direct current power converter

24

which is attached to an existing alternating current power source (VAC). In this embodiment, the garage door opener GDO can also be activated by overriding the remote receiver

14

by using a manual button MNL.

FIG. 2

shows a perspective view

26

of the remote emitter

12

and portrays how the remote emitter

12

would be installed in a cigarette lighter receptacle

28

which is located in a vehicle V. The lighter receptacle

28

is supplied with a direct voltage source BAT from the vehicle V, with a positive polarity connection

30

and a negative polarity connection

32

.

The emitter body

34

of the remote emitter

12

is an exterior housing that encloses the internal components of the remote emitter

12

. An emitter retainer

36

is used to correctly locate the remote emitter

12

within the lighter receptacle

28

. The emitter retainer

36

also acts as an electrical conducting channel between the remote emitter

12

and the negative polarity connection

32

. A switch

37

is located on top of the emitter body

34

, which is manually activated by the user to power the remote emitter

12

and send a serial coded pulse train

16

.

A view of the installed controller

38

is shown in FIG.

3

. The remote emitter

12

is installed in a lighter receptacle

28

which is located inside a vehicle V. The lighter receptacle

28

is located in different locations within the vehicles V of various manufacturers, but is usually located on the dashboard D or a console C, as indicated by FIG.

3

. The location of the lighter receptacle

28

is designed by vehicle manufacturers to be conveniently accessed by the driver or passenger while they are seated in seats S.

FIG. 3

also portrays how the remote emitter

12

would be used to transmit a coded signal pulse train

16

towards a garage G and a garage door GD. As a driver located in vehicle V approaches a garage G, the driver can easily reach and activate the remote emitter

12

by simply pushing down the switch

37

on top of the emitter body

34

. Upon activation, the remote emitter

12

emits the coded serial pulse train

16

, which includes a unique transmitter code

20

(one of 19,683) on a 380 MHz carrier frequency.

FIG. 4

shows a detailed illustration

40

of an approaching vehicle V as it arrives at a residential building B and a garage G. The coded serial pulse train

16

is transmitted from a remote emitter

12

located in the vehicle V. In this application, the pulse train

16

is used to activate a remote receiver

14

that can provide the logic necessary to open or close a garage door GD.

FIG. 5

is a depiction

42

of an alternative embodiment of the present invention in which the remote receiver

14

is contained within an integrated garage door opener

44

.

FIG. 6

is a plan view

46

of some of the many useful applications for which the Miniature Remote Control System

10

may be used. Upon arriving at or departing from a building B, a user in vehicle V can activate the remote emitter

12

to send a coded serial pulse train

16

to a security gate receiver

48

in order to open or close a security gate SG. Exterior lighting EL can be controlled in a similar manner using an exterior light receiver

50

. Sprinklers LC can be activated or shut off using a landscape control receiver

52

, thus allowing the vehicle passengers to exit the vehicle V without getting wet. The remote emitter

12

may also be used to arm or to disarm a home alarm and security system SA by using a security system receiver

54

. Other devices inside the building B may activated, by using a remote emitter

12

to activate an interior lighting receiver

56

to turn lights IL off or on around the house B, or by activating a climate control receiver

58

to operate heating and air conditioning systems AC.

A schematic diagram of the transmitter circuitry

60

within the remote emitter

12

is revealed in FIG.

7

. To activate the remote emitter

12

, the user simply pushes down the switch

37

on the emitter body

34

, which allows the transmitter circuitry

60

to be energized with the 13.7 volt DC power supplied by the positive polarity connection

30

and the negative polarity connection

32

in the vehicle V.

The transmitter circuitry

60

incorporates three primary systems, including the emitter power supply

62

, the emitter encoder

64

, and the emitter oscillator

66

. The emitter power supply

62

provides filtered direct voltage power to the emitter encoder

64

and the emitter oscillator

66

. The emitter encoder

64

uses an encoding chip

68

, which in this embodiment is an MC 145026, manufactured by Motorola. Nine trinary code input traces

70

are supplied into the encoding chip

68

. When the transmitter circuitry

60

is manufactured, the input traces

70

are selectively cut to produce high, low, or open states. In this manner, each remote emitter

12

produced can have one of 19,683 unique transmitter codes

20

, derived from

3

9

possible configurations.

A timing network

72

is also provided within the emitter encoder

64

. The timing network

72

consists of an RTC timing resistor

74

, a CTC timing capacitor

76

, and a source resistor

78

. The source resistor

78

is used as a buffer for the timing network

72

. The clock frequency of the encoder

64

is determined by the selection of values for the RTC timing resistor

74

and the CTC timing capacitor

76

. This frequency is determined by the following relationship:

Clock Frequency (cycles/sec)=1/(2.3

*CTC*RTC

).

To obtain more unique transmitter codes

20

for the remote emitter

12

than the 19,683 possible combinations offered by the encoding chip

68

alone, values of the RTC timing resistor

74

and the CTC timing capacitor

76

can be changed.

When activated, the emitter oscillator

66

produces the encoded serial pulse train

16

. A 1.0 uH 5% emitter inductor

80

acts as a filter in the transmitter circuitry

60

to isolate the 380 MHz signal produced by the emitter oscillator

66

from the clean voltage necessary for operation of the encoding chip

68

. A signal resistor

82

is located between the emitter encoder

64

and the emitter oscillator

66

. The value chosen for the signal resistor

82

determines the transmission power of the remote emitter

12

. In the preferred embodiment, a 33K signal resistor

82

is used to provide interference free operation between the remote emitter

12

and a remote receiver

14

up to 200 feet away. Appropriate values for the signal resistor

82

are also limited by the maximum allowable transmission power dictated by the Federal Communications Commission (FCC).

A coupling transformer

81

is used to isolate the transmitter circuitry

60

from the emitter antenna

83

. This creates a better impedance match between the transmitter circuitry

60

and the emitter antenna

83

. In one embodiment of the invention, a circuit trace

122

on the bare production transmitter board

118

may be employed as an antenna for the remote emitter

12

. In another embodiment of the present invention, the emitter switch

37

is linked to the emitter oscillator

66

. When the switch

37

is depressed by the user, the user becomes the emitter's antenna, and provides an unobstructed line of sight for the coded serial pulse train

16

through the vehicle windshield WS.

FIG. 8

is a schematic diagram of the receiver circuitry

84

used with the remote receiver

14

. The incoming 380 MHz serial pulse train signal

16

arrives at the receiver antenna

18

, and is then processed by an rf super-regenerative receiver

86

. The super-regenerative receiver

86

operates with an extremely wide bandwidth, which allows the Miniature Remote Control System

10

to operate over a very large temperature range. Since the ambient temperature of the remote emitter

12

in a vehicle V or the remote receiver

14

in a building B can commonly be anywhere from 15 degrees F to 130 degrees F, the 380 MHz coded serial pulse train

16

can have a tolerance of as much as +/−5 MHz.

A high frequency filtering circuit

88

is coupled to the super-regenerative receiver

86

. Two 0.001F high frequency filter capacitors

90

are coupled to a filter transistor

92

. The high frequency filter capacitors

90

act as a buffer between the super-regenerative receiver

86

and the receiver amplifier

94

and data separator

98

circuits.

A data amplifier

94

is then used to begin to amplify the encoded serial pulse train

16

. An operational amplifier

96

is used to amplify the 10 KHz serial pulse train

16

by a factor of 10. The operational amplifier

96

has a low frequency bandwidth of only 1-4 MHz, and acts to further filter any residual high frequency components.

A data separator

98

is coupled to the receiver amplifier

94

. The data separator

98

adjusts itself to the output signal of the first operational amplifier

96

, to allow for signal shift due to temperature variations in the remote emitter

12

. The data separator

98

uses a second operational amplifier

100

to compare the actual serial pulse train

16

to the averaged dc level of the serial pulse train

16

. A slight amount of hysteresis is added through a 1.5 Meg-ohm resistor

101

. This provides clean switching and enhanced noise rejection. The output of the data separator

98

is a faithful reproduction of the serial pulse train

16

output from the emitter encoder

64

.

The remaining serial pulse train

16

is output from the data separator

98

to a receiver decoder

102

, which in this embodiment is an MC 145028, manufactured by Motorola. The receiver decoder

102

is preset when manufactured with a trinary receiver code

22

to match the transmitter code

20

from the encoding chip

68

in the remote emitter

12

. The receiver decoder

102

compares the transmitter code

20

to the receiver code

22

. If the two codes

20

&

22

are identical for two sequential serial pulse trains

16

received from the remote emitter

12

, the receiver decoder

102

supplies the necessary logic to trigger a relay

104

that will activate the

16

volt DC signal

106

necessary to implement the exterior device ED, such as a garage door opener GDO.

FIG. 9

is a schematic of the receiver power supply

108

which is used to supply the regulated 12 volt DC power necessary for proper function of the receiver circuitry

84

as well as the 16 volt DC power

106

necessary to power the relay

104

.

FIG. 10

shows the first receiver circuit board

110

used in the 380 MHz remote receiver circuitry

84

, which includes the super-regenerative receiver

86

, the receiver amplifier

94

, and the data separator

98

.

FIG. 11

reveals a second receiver circuit board

112

that is used in conjunction with the first receiver circuit board

110

to complete the receiver circuitry

84

within the remote receiver

14

. The second receiver circuit board

112

includes the receiver decoder

102

and the receiver power supply

108

.

For the remote emitter

12

to fit within in a small area such as a lighter receptacle

28

within a vehicle V, the transmitter circuitry

60

must be able to be packaged within an extremely small volume.

FIGS. 12 through 16

illustrate different views of the components that make up the transmitter circuitry

60

within the remote emitter

12

.

FIG. 12

shows a top view the stacked production transmitter board

114

that achieves all the functionality required of the transmitter circuitry

60

in a micro-miniature design that can fit within the emitter body

34

of the remote emitter

12

.

FIG. 13

reveals a side view

116

of the production transmitter board

114

, whose components and layout have been advantageously chosen to minimize the exterior dimensions of the transmitter circuit board

114

.

FIG. 14

illustrates details the component side of the bare production transmitter board

118

, from which components are assembled to make up the completed production transmitter board

114

. The bare transmitter board

118

is designed to preserve the compact nature of the completed transmitter board

114

, while minimizing trace path lengths, and providing adequate room for assembly, quality control, and heat rejection.

FIG. 15

provides a detailed view

120

of the circuit side of the bare transmitter board

118

. All board traces

122

on the bare transmitter board

118

are designed to be as short as possible to minimize circuit response time and heat loss, while still providing adequate distance between traces

122

to avoid malfunctions.

FIG. 16

provides a composite view

124

of the production transmitter board

114

. This view exemplifies how the components that make up the board

114

have been arranged to advantageously provide an extremely small volume while still allowing adequate room for manufacture, heat rejection, and testing.

FIG. 17

is a top view of a preferred surface-mounted transmitter embodiment

126

. The surface-mount transmitter

126

provides all the functionality required for the remote emitter

12

, while advantageously employing surface-mounted component assembly design. As the remote emitter

12

can be used for numerous applications, the cost to manufacture the components must be considered to provide as large an installed customer base as possible. Modern automated manufacturing methods and the availability of high quality “surface-mount” electronic components at a reasonable cost has made the surface-mount transmitter

126

desirable to achieve the lowest possible cost of the present invention for the user.

FIG. 18

reveals a detailed plan view

128

of the remote emitter

12

. The surface-mount transmitter board

126

is installed inside the emitter body

34

. To provide the mechanical connection to locate the remote emitter

12

within the lighter receptacle

28

, and to provide the proper electrical pathway between the remote emitter

12

and the negative polarity connection

32

, an emitter retainer

36

is provided. The emitter retainer

36

is attached to the emitter body

34

with a spring

130

and a snap ring

132

. The spring

130

and snap ring

132

act to provide the user of the remote emitter

12

with a tactile feel when the button

37

is pushed, similar to the spring loaded “snap” of a calculator keypad button that provides a user with a tactile response.

FIG. 19

provides a detailed side view

134

of the embodiment of the remote emitter

12

shown in FIG.

18

. This view illustrates how the necessary electronic components that make up the surface mount transmitter

126

are placed to fit within the confines of the emitter body

34

with generous tolerances, allowing the use of multiple parts sourcing for non-interrupted, large-volume manufacture of the remote emitter

12

.

FIG. 20

provides an enlarged cut-away plan view of an alternate transmitter embodiment

136

of the remote emitter

12

. From this view it can be seen how the surface-mount transmitter circuit board

126

that provides all the required functionality of the remote emitter

12

can be conveniently packaged within the exterior body

34

that can be installed in a common lighter receptacle

28

.

FIG. 21

is an enlarged sectional side view

138

of the alternate transmitter embodiment

136

shown in FIG.

20

. In this view the transmitter conductive pathway

140

is shown. The conductive pathway

140

makes contact with the positive polarity connection

30

in the vehicle V when the user pushes the button

37

to activate the remote emitter

12

. This powers the remote emitter

12

to send a coded serial pulse train

16

to the remote receiver

14

for remote control of an external device ED, such as a garage door opener GDO.

The lighter receptacles

28

and the interior design requirements of vehicles V produced by various manufacturers require that the remote emitter

12

be packaged with slightly different geometries and styling. The production transmitter board

114

is designed to be located within all appropriate emitter bodies

34

which are designed to fit within the standard lighter receptacles

28

of vehicles V produced by substantially all manufacturers.

FIG. 22

shows a side view of a remote emitter

141

designed to fit in a Lincoln™ automobile.

FIG. 23

reveals a side view of a remote emitter

142

designed to be used in a Mercedes Benz™.

FIGS. 24 and 25

are detailed expanded and installed assembly views of an alternate embodiment of the extended remote emitter

144

. This configuration allows expanded functionality and versatility that is advantageous for many users. The extended remote emitter

144

allows the user to control multiple devices ED remotely from a vehicle V, by providing the circuitry and controls to send a number of unique coded serial pulse trains

16

to different external devices ED, such as a garage door opener GDO, a security system receiver

54

, a lighting control receiver

56

, and a security gate receiver

48

. The multiple button keypad

146

shown in

FIG. 24

has single buttons

148

devoted to single transmitting functions. Other embodiments that require increased security or the use of a small number of buttons

148

to control a large number of external devices ED may use a keyed combination of required button strokes to provide the correct coded serial pulse train

16

to operate external devices ED.

The location of the multiple button keypad

146

for this embodiment is placed to be easily seen and operated by the user within the vehicle V. To enhance the ease with which the extended remote emitter

144

is used, the single buttons

148

can be color keyed, illuminated, or supplied with names or icons to identify the functions for which they are to be used.

Another feature of the extended remote emitter

144

is the extension receptacle

150

that is shown in FIG.

24

. Many modern vehicles V are equipped with optional accessories ACC such as portable cellular phones CP, which often use the lighter receptacle

28

within a vehicle V to supply DC power. The extension receptacle

150

provided by the extended remote emitter

144

allows the attachment of additional accessories ACC, such as cellular phones CP. As the extended remote emitter

144

is designed to draw a very small amount of power from the vehicle DC power source BAT, the use of both the extended emitter

144

and a cellular phone CP within the lighter receptacle

28

is within the amperage limits of vehicle electrical circuit BAT, which is designed to power a cigarette lighter CL.

FIG. 26

reveals a block diagram of another alternate embodiment of the present invention, the Miniature Transceiver Control System

152

, which comprises a remote transceiver

154

in a vehicle V, and a secondary transceiver

156

attached to external devices ED. The Miniature Transceiver Control System

152

provides both remote control of external devices ED from a vehicle V, and communication back to the remote transceiver

154

from the secondary transceiver

156

.

The Miniature Remote Transceiver System

152

is able to transmit and receive information on a carrier frequency of 902 to 928 MHz. The Federal Communications Communication (FCC) allows a high maximum transmission power for systems operating in the 900 MHz bandwidth. Operation of the Miniature Transceiver Control System

152

in this 900 MHz frequency band allows the system to operate with a range exceeding two miles, while advantageously providing interference free operation from obstacles, such as the vehicle body VB, buildings B, and garage walls GW.

A user in a vehicle V can activate the remote transceiver

154

to send a coded serial pulse train

16

by simply pressing down on buttons

148

located on the transceiver keypad

160

. Activation of a desired coded serial pulse train

16

may be accomplished with a stroke of an individual button

148

, or may be accomplished with a more elaborate predetermined combination of multiple buttons

148

. The transceiver keypad

160

is coupled in series to a transceiver microprocessor

162

, a transceiver transmitter

164

, and a transceiver antenna

166

. When the user supplies the correct transmitter code

20

to the transceiver microprocessor

162

, the transceiver microprocessor

162

activates the transceiver transmitter

164

to send the appropriate coded serial pulse train

16

containing the transmitter code

20

. The coded serial pulse train

16

provided by the transceiver transmitter

164

is broadcast from the vehicle V, through the transceiver antenna

166

, toward the secondary transceiver

156

.

The secondary transceiver

156

is typically located in a building B, and is powered by a standard 120 volt alternating current source VAC. The secondary transceiver

156

has inputs for connection to external devices ED, such as security and alarm systems SA, fire detectors FD, garage door openers GDO, and heating and air conditioning systems AC.

The secondary transceiver

156

is able to receive, amplify, and decode the coded serial pulse train

16

sent by the remote transceiver

154

, and is able to activate external devices ED, such as security and alarm systems SA and garage door openers GDO. The secondary transceiver

156

is also able to transmit an information pulse train

158

back to the remote transceiver

154

.

The remote transceiver

154

is able to receive the information pulse train

158

from the secondary transceiver

156

. The information pulse train

158

may contain information for use by the transceiver microprocessor

162

, such as new transmitter codes

20

required to provide remote control for external devices ED. The information pulse train

158

may also contain information to be communicated to the user, such as the status of external devices ED, or confirmation of commands sent to the secondary transceiver

156

by the remote transceiver

154

. Information regarding the status of external devices ED that can be transmitted to the user may be of great value to the user in a vehicle V. Criminal activity that activates a security and alarm system SA which is connected to a secondary transceiver

156

in a building B can be communicated to a user in a vehicle V. A fire within a building B that activates a fire detector FD which is connected to a secondary transceiver

156

can be communicated to a user.

The information pulse train

158

sent by the secondary transceiver

156

enters the remote transceiver

154

through the transceiver antenna

166

. The transceiver antenna

166

is coupled in series to the transceiver receiver

168

, the transceiver microprocessor

162

, and a backlit liquid crystal display

170

. The transceiver microprocessor

162

is also coupled to function LEDs

172

. When an information pulse train

158

arrives at the transceiver antenna

166

, it is processed by the transceiver receiver

168

and sent to the transceiver microprocessor

162

. If the information pulse train

158

contains information for use only by the transceiver microprocessor

162

, such as a new transmission code

20

, the transceiver microprocessor

162

stores the new transmission code

20

in its memory. If the information pulse train

158

contains information to be communicated with the user in the vehicle V, the transceiver microprocessor

162

sends the information to the liquid crystal display

170

or to the function LEDs

172

, where the information is provided to the user.

FIG. 27

is a perspective illustration

174

of the remote transceiver

154

, as it would be installed in the console C of a vehicle V. In this embodiment, the remote transceiver

154

is designed to fit within a standard ash tray AT in a vehicle V. A power pickup

176

is provided on the remote transceiver

154

to supply power to the remote transceiver

154

from the vehicle DC power source BAT. The power pickup

176

is designed to fit within a standard cigarette lighter receptacle

28

. The transceiver keypad

160

is conveniently located on the upper surface of the remote transceiver

154

. A backlit liquid crystal display

170

and a function LED

172

are also provided on the upper surface of the remote transceiver

154

, to provide communication to the user from the secondary transceiver

156

in the house B. An extension receptacle

150

is also provided on the remote transceiver

154

to provide a means for attachment of additional accessories ACC, such as cellular phones CP. To install the remote transceiver

154

, the cigarette lighter CL and ash tray AT can simply be removed and replaced with the remote transceiver

154

.

FIG. 28

is a block diagram of the power circuitry

178

for the remote transceiver

154

. Power is supplied to the remote transceiver

154

from the vehicle DC power source BAT through the power pickup

176

. A transceiver power supply

180

is located within the remote transceiver

154

, and is coupled to the power pickup

176

. The transceiver power supply

180

conditions the DC power source BAT to provide appropriate power outputs

182

for components in the remote transceiver

156

and for secondary accessories ACC that are coupled to the extension receptacle

150

.

Alternate Antenna Configurations

The operating frequency and radiated power of the present invention is regulated by the FCC. This device must operate within the constraints of those regulations. Under Section 15.231, periodic operation in the band 40.66-40.70 MHz and above 70 MHz of remote control devices such as garage door openers are allowed. Since the allowable radiated field strength is low (<12,500 μV/meter average value measured at 3 meters for frequencies above 470 MHz), the method of coupling the RF energy into the antenna can be primarily driven by economics as opposed to power efficiency. Most importantly, the RF energy must exit the car, usually through a multipath composing of several reflections, and enter the house or a garage where a receiver intercepts the signal and operates the garage door or other device.

Modulation & Message Coding

The basic system operates at 900 MHz when the operator presses the button labeled “Close Switch.” At the time of switch closure, the transmitter begins sending a coded message to the receiver. Once activated by the switch, the transmitter automatically ceases transmission within five seconds after the switch is released. There are two key features of the coded message. First, a unique code is repeatedly transmitted. The receiver is designed to look for codes that have been identified as valid for executing the desired remote function such as opening the garage door. The receiver must receive the same correct code three times before it allows the remote operation. The fact that three correct codes must be received is based upon current technology. The intent is to avoid susceptibility to random noise. In fact, more than three makes for a more robust system. The only problem with increased required occurrences is the length of time the operator must wait before the remote device begins to respond. The present invention is designed to make the reaction appear to be instantaneous from a user's point of view. To take advantage of power averaging, the code will be repeated at a rate of twenty times per second on average. Secondly, the transmitter uses an “ALOHA” messaging scheme. ALOHA is a messaging technique that allows multiple users to operate simultaneously on the same frequency.

When dealing with shared channels (a channel being an assigned frequency band), one must be prepared to resolve conflicts that arise when more than one demand is placed on the channel. For example, in the case of multiple garage door devices within close proximity, whenever a portion of the transmission of one user overlaps with the transmission of another user, then the two collide and “destroy” each other, unless a random access technique such as ALOHA is utilized.

Pure ALOHA permits a user to transmit any time it desires. If a user transmits a code word, and within some appropriate time-out period following its transmission it receives an acknowledgment from the destination, then it knows that no conflict occurred. Otherwise, it assumes that a collision occurred and it must retransmit. To avoid continuously repeated conflicts, The retransmission delay is randomized across the transmitting devices, thus spreading the retry packets over time. This approach works most effectively with a transceiver on both ends. However, that basic ALOHA approach still works using the operator as the feedback for acknowledging the garage door has opened or closed. A basic system using ALOHA, the transmitter sends a coded message upon switch closure and then waits a period of time before retransmitting the message. This process is repeated until the operator releases the switch. The delay between messages is a random period of time. The time between messages is long with respect to the time it takes to transmit a message. The transmitter codes the RF using pulse modulation. Therefore, the transmitter does not emit RF energy while waiting to send the message.

Basic Receiver

The receiver is operational at all times waiting for the correct message to be decoded by the RF receiver. After the receiver get three valid messages, the remote operation is performed such as opening a garage door. This is one of three basic modes of operation. The second mode of operation is the entry of new valid codes. This is achieved by holding down the programming button “switch” and operating the new transmitter. The receiver reads in the coded message and saves the code word in the non volatile random access memory NOVRAM. The new transmitter is now capable of operating the remote system. The third mode of operation is clearing or resetting of all stored codes in the NOVRAM of the receiver. This is done by turning power on while the programming button is pressed. Upon boot-up the microcontroller recognizes the depressed programming button and then erases the contents of the NOVRAM.

Manufacturing

For low cost manufacturing purposes, all receivers are initially configured during the manufacturing process with the same code. This is accomplished within the software design. This allows for simple testing of the receiver as it is being built.

The transmitter randomly selects a code word on initial power up. This gives the transmitter a unique code word that is stored in NOVRAM. The random selection of the code word is done partly with the hardware timer that is built into the microcontroller and through a software timer. Upon the initial power-on and boot-up process the microcontroller checks to verify that a valid code word has been stored in the NOVRAM. If there is no code word the microcontroller starts the hardware and software timers. The operator, some random time later, will push the button marked “Close the switch.” This stops the counters and the microcontroller loads the contents of the counters into the NOVRAM as the valid code word. The operator is most likely to be a technician during the testing phase of the manufacturing process. The microcontroller is capable of counting very fast. The hardware and software counters count from zero to maximum count more than twenty times a second. After maximum count the counters automatically start over at zero. The operator pressing the button randomizes the process. This random number algorithm can produce over a billion unique code words.

This method allows the transmitters and receivers to be built and tested independently. Transmitters and receivers are not matched pairs, nor do they require the setting of DIP (dual in-line package) switches. Replacement transmitters can be purchased and programmed into the receiver.

The invention also provides several alternative methods of programming the transmitter with unique codes. An additional connector could be used to down load information. However, this concept is inferior due to the cost and physical location constraints of the application. Instead, a technique has been developed that allows the information to be encoded on the power supply leads. Therefore, the unique codes can be downloaded without adding additional cost or complexity to the transmitter circuit. This is an important concept for making transmitters compatible with or vendors receivers. Current state of the art devices change codes by selecting settings on a DIP switch, on both the transmitter and receiver. With this embodiment, the user can program the transmitter with a compatible code and then set the dip switches on the receiver to match the transmitter. It is envisioned that a distributor will sell transmitters independent of the receiver for replacement of lost or broken transmitters. The distributor would concurrently provide a service of allowing the user to select a code to be programmed into the transmitter NOVRAM. This is accomplished with a special box that the user can plug the transmitter into and activate the programmer. The process only takes a few seconds and allows the user to either pick a code or allow the box to randomly select a code and then print out the code word so that the dip switches can be properly set on the receiver.

CONCLUSION

Although the present invention has been described in detail with reference to particular preferred and alternative embodiments, persons possessing ordinary skill in the art to which this invention pertains will appreciate that various modifications and enhancements may be made without departing from the spirit and scope of the Claims that follow. The imaging equipment that has been disclosed above is presented to educate the reader about particular embodiments, and is not intended to constrain the limits of the invention or the scope of the Claims. The List of Reference Characters which follows is intended to provide the reader with a convenient means of identifying elements of the invention in the Specification and Drawings. This list is not intended to delineate or narrow the scope of the Claims.

LIST OF REFERENCE CHARACTERS

10

Miniature Remote Control System

12

Remote emitter

14

Remote receiver

16

Coded serial pulse train

18

Receiver antenna

20

Transmitter code

22

Receiver code

24

Receiver power converter

26

Perspective view of remote emitter

28

Cigarette lighter receptacle

30

Positive polarity connection

32

Negative polarity connection

34

Emitter body

36

Emitter retainer

37

Switch

38

Installed Controller

40

Illustration of approaching vehicle

42

Depiction of integrated garage door opener

44

Integrated garage door opener

46

Plan view of applications

48

Security gate receiver

50

Exterior light receiver

52

Landscape control receiver

54

Security system receiver

56

Interior lighting receiver

58

Climate control receiver

60

Transmitter circuitry

62

Emitter power supply

64

Emitter encoder

66

Emitter oscillator

68

Encoding chip

70

Trinary code input traces

72

Timing network

74

RTC timing resistor

76

CTC timing capacitor

78

Source resistor

80

Emitter inductor

81

Coupling transformer

82

Signal resistor

83

Emitter antenna

84

Remote receiver circuitry

86

Super-regenerative receiver

88

High frequency filtering circuit

90

High frequency filter capacitor

92

Filter transistor

94

Data amplifier

96

First operational amplifier

98

Data separator

100

Second operational amplifier

102

Receiver decoder

104

Relay

106

16 volt DC signal

108

Receiver power supply

110

First receiver board

112

Second receiver board

114

Production transmitter board

116

Side view of production transmitter board

118

Bare transmitter board

120

Circuit side of bare production board

122

Board traces

124

Composite view of production transmitter board

126

Surface mounted transmitterboard

128

Plan view of remote emitter

130

Spring

132

Snap ring

134

Detailed side view of remote emitter

136

Alternate transmitter embodiment

138

Sectional side view of alternate transmitter embodiment

140

Conductive pathway

141

Remote emitter to fit in Lincoln ™ automobile

142

Remote emitter to fit in Mercedes Benz ™ automobile

144

Extended remote emitter

146

Multiple button keypad

148

Single button

150

Extension receptacle

152

Miniature Transceiver Control System

154

Remote transceiver

156

Secondary transceiver

158

Information pulse train

160

Transceiver keypad

162

Transceiver microprocessor

164

Transceiver transmitter

166

Transceiver antenna

168

Transceiver receiver

170

Liquid crystal display

172

Function LEDs

174

Perspective illustration of remote transceiver

176

Power pickup

178

Remote transceiver power circuitry

180

Transceiver power supply

182

Power outputs

AC

Heating and air conditioning system

ACC

Secondary accessories

ANT

Antenna

AT

Standard ashtray

B

Building

BAT

Vehicle DC power source

BT

Button

C

Console

CA

Cap

CL

Cigarette lighter

CP

Cellular phone

D

Dashboard

ED

External device

EL

Exterior lighting

FD

Fire detector

G

Garage

GD

Garage door

GDO

Garage door opener

G

Garage wall

GR

Ground ring

IL

Indoor lighting

LC

Sprinklers

M

Mold

MNL

Manual button

PCB

Printed circuit board

PL

Power lead

PP

Pressure plate

PR

Power ring

S

Passenger seating

SA

Security and alarm system

SG

Security gate

V

Vehicle

VAC

Alternating current power source

VB

Vehicle body

W

Windshield

Number	Name	Date	Kind
3906348	Wilmott	Sep 1975	A
3967133	Bokern	Jun 1976	A
4241870	Marcus	Dec 1980	A
4286262	Wahl	Aug 1981	A
4409592	Hunt	Oct 1983	A
4529980	Liotine	Jul 1985	A
4665395	Van Ness	May 1987	A
4771399	Snowden	Sep 1988	A
4827520	Zeinstra	May 1989	A
4912463	Li	Mar 1990	A
4988992	Heitschel	Jan 1991	A
5007863	Xuan	Apr 1991	A
5073721	Terrill	Dec 1991	A
5148159	Clark	Sep 1992	A
6154544	Farris et al.	Nov 2000	A

Miniature remote control system

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS & CLAIMS FOR PRIORITY

US Referenced Citations (15)