US20070100470A1 - Two sensor movement - Google Patents
Two sensor movement Download PDFInfo
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- US20070100470A1 US20070100470A1 US11/643,566 US64356606A US2007100470A1 US 20070100470 A1 US20070100470 A1 US 20070100470A1 US 64356606 A US64356606 A US 64356606A US 2007100470 A1 US2007100470 A1 US 2007100470A1
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- control
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- 238000000034 method Methods 0.000 claims abstract description 56
- 230000003213 activating effect Effects 0.000 claims description 189
- 230000004913 activation Effects 0.000 claims description 22
- 230000008859 change Effects 0.000 claims description 6
- 230000003247 decreasing effect Effects 0.000 description 4
- 238000013479 data entry Methods 0.000 description 3
- 230000006872 improvement Effects 0.000 description 2
- 230000009471 action Effects 0.000 description 1
- 230000007812 deficiency Effects 0.000 description 1
- 230000009977 dual effect Effects 0.000 description 1
- 239000012528 membrane Substances 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000003287 optical effect Effects 0.000 description 1
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Classifications
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/033—Pointing devices displaced or positioned by the user, e.g. mice, trackballs, pens or joysticks; Accessories therefor
- G06F3/038—Control and interface arrangements therefor, e.g. drivers or device-embedded control circuitry
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0481—Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor's changing behaviour or appearance
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0481—Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor's changing behaviour or appearance
- G06F3/04815—Interaction with a metaphor-based environment or interaction object displayed as three-dimensional, e.g. changing the user viewpoint with respect to the environment or object
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/30—Nc systems
- G05B2219/35—Nc in input of data, input till input file format
- G05B2219/35462—Mouse
Definitions
- This invention relates to a method of control using only two sensors.
- the main objective of the present invention is to overcome all the deficiencies found in all prior art devices for two sensor control.
- any two binary sensors or two variable controlled sensors to control the state of an object in a first state by activating a first sensor, control the state of an object in a second state by activating a second sensor, control the state of an object in a third state by activating a first sensor and a second sensor simultaneously and control the state of an object in a fourth state by deactivating and reactivating a first sensor and a second sensor simultaneously.
- Control of any object, robot, cursor, machine, virtual reality environment, etc. in a one dimensional environment or two dimensional environment can easily be obtained using only two sensors.
- a computer mouse is one preferred embodiment of the invention.
- the ability to use a two sensor keyboard to reverse the last change made or to reverse the last undo made while using a pointing device in a graphics program will increase the speed and efficiency in any graphics program or any other two axis cursor pointing program.
- One preferred embodiment of the present invention allows multiple methods of control using only two sensors. Simultaneously activating a first sensor and a second sensor followed by simultaneously deactivating a first sensor and a second sensor will exit a first mode and enter a second mode. Independently activating a first sensor will control the state of an object in a first state. Deactivating a first sensor will stop control in a first state. Independently activating a second sensor will control the state of an object in a second state. Deactivating a second sensor will stop control in a second state. Simultaneously activating a first sensor and a second sensor followed by simultaneously deactivating a first sensor and a second sensor will exit a second mode and enter a third mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor to reverse the last change. Independently activating a second sensor to reverse the last undo.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor will control the state of an object in a first state. Deactivating a first sensor will stop control in a first state. Independently activating a second sensor will control the state of an object in a second state. Deactivating a second sensor will stop control in a second state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Deactivating a second sensor will control the state of an object in a fifth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Deactivating a first sensor will control the state of an object in a sixth state.
- Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Simultaneously deactivating a first sensor and a second sensor will stop control in a third state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Deactivating a second sensor will control the state of an object in a seventh state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Deactivating a first sensor will control the state of an object in an eighth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Simultaneously deactivating a first sensor and a second sensor will stop control in a fourth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor of a second set of two sensors will control the state of an object in a ninth state. Deactivating a third sensor will stop control in a ninth state. Independently activating a fourth sensor of a second set of two sensors will control the state of an object in a tenth state. Deactivating a fourth sensor will stop control in a tenth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state. Deactivating a fourth sensor will control the state of an object in an eleventh state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state.
- Deactivating a third sensor will control the state of an object in a twelfth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state. Simultaneously deactivating a third sensor and a fourth sensor will stop control in a third state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Deactivating a fourth sensor will control the state of an object in a thirteenth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Deactivating a third sensor will control the state of an object in a fourteenth state.
- Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Simultaneously deactivating a third sensor and a fourth sensor will stop control in a fourth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state.
- Another preferred embodiment of the present invention allows another method of control and rate of control using only two sensors.
- Using any adjustable sensor will increase or decrease the rate of an object by producing different degrees of activation.
- Activating an adjustable first sensor will control the state of an object.
- Increasing the activation parameters of an adjustable first sensor will increase the rate of control of an object and decreasing the activation parameters of an adjustable first sensor will decrease the rate of control of an object.
- Activating an adjustable second sensor will control the state of an object.
- Increasing the activation parameters of an adjustable second sensor will increase the rate of control of an object and decreasing the activation parameters of an adjustable second sensor will decrease the rate of control of an object.
- the system and method of the two sensor control invention are logically developed, relatively easy to learn and very quick to use.
- FIG. 1 Illustrates one preferred arrangement of a two sensor embodiment found in the disclosed invention.
- FIG. 2 Illustrates one preferred arrangement of a two sensor embodiment found in the disclosed invention.
- FIG. 3 Illustrates one preferred arrangement of a horizontal first set of two sensors embodiment combined with a vertical second set of two sensors embodiment positioned on the left, found in the disclosed invention.
- FIG. 4 Illustrates one preferred arrangement of a horizontal first set of two sensors embodiment combined with a vertical second set of two sensors embodiment positioned on the right, found in the disclosed invention.
- FIGS. 1, 2 , 3 and 4 in the preferred embodiment's simplest binary sensor on/off method form.
- One preferred embodiment of the present invention uses any two binary sensors or two variable controlled sensors for control in a first state by activating a first sensor, and in a second state by activating a second sensor. Control of any object, robot, cursor, machine, virtual reality environment, etc. in a one dimensional environment or two dimensional environment can easily be obtained using only two sensors.
- a computer mouse is one preferred embodiment of the invention.
- Other examples of two sensor preferred embodiments of the invention are the cursor left and cursor right keys on a standard computer keyboard, the left and right space bar keys on a split space bar computer keyboard, any two keys on a standard computer keyboard, any two keys on any keyboard or data entry device ever produced or will ever be produced.
- Any two binary sensors or two variable controlled sensors includes but is not limited to: accelerometers, biometric sensors, biosensors, flex sensors, micro force sensors, motion sensors, optical sensors, piezoelectric force sensors, position sensors, pressure sensors, temperature sensors, touch sensors, touch screen sensors, contact switch, detector switch, dimmer switch, dual motion switch, electromechanical switch, key switch, membrane switch, pushbutton switch, rocker switch, rotary switch, snap action switch, toggle switch, vertical touch switch, and the like.
- One preferred embodiment of the present invention allows multiple methods of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right.
- Deactivating a second sensor, preferably a right sensor will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will exit a second mode and enter a third mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right.
- Deactivating a second sensor, preferably a right sensor will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will exit a second mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right.
- Deactivating a second sensor, preferably a right sensor will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will exit a second mode and enter a third mode.
- Independently activating a first sensor preferably a left sensor, will control the state of an object in a first state, preferably to the left.
- Deactivating a first sensor preferably a left sensor
- a second sensor Independently activating a second sensor, preferably a right sensor
- Deactivating a second sensor preferably a right sensor
- a second sensor will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right.
- Deactivating a second sensor, preferably a right sensor will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will exit a second mode and enter a third mode.
- Independently activating a first sensor preferably a left sensor, will delete data in a first state, preferably to the left of an object.
- Deactivating a first sensor preferably a left sensor
- a second sensor Independently activating a second sensor, preferably a right sensor, will delete data in a second state, preferably to the right of an object.
- Deactivating a first sensor preferably a left sensor
- Deactivating a first sensor will stop deleting data in a second state, preferably to the right of an object.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a third mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, to reverse the last change. Independently activating a second sensor, preferably a right sensor, to reverse the last undo.
- One preferred embodiment of the present invention uses any two binary sensors or two variable controlled sensors to control the state of an object in a first state by activating a third sensor, control the state of an object in a second state by activating a fourth sensor, control the state of an object in a third state by activating a third sensor and a fourth sensor simultaneously and control the state of an object in a fourth state by deactivating and reactivating a third sensor and a fourth sensor simultaneously.
- a second set of two sensors allows complete control in a three dimensional environment.
- a computer mouse and two keys on any keyboard are preferred embodiments of the invention.
- two sensor preferred embodiments of the invention are the cursor left and cursor right keys combined with any other two keys on a standard computer keyboard, the left and right space bar keys combined with any other two keys on a split space bar computer keyboard, any two keys combined with any other two keys on a standard computer keyboard, any two keys combined with any other two keys on any keyboard or data entry device ever produced or that will ever be produced.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward.
- Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a fourth state, preferably backward. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object upward.
- Simultaneously deactivating a first sensor preferably a left sensor, and a second sensor, preferably a right sensor
- a first sensor preferably a left sensor
- a second sensor preferably a right sensor
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will control the state of an object upward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a fifth state, preferably forward and to the left. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Deactivating a first sensor, preferably a left sensor, will control the state of an object in a sixth state, preferably forward and to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a seventh state, preferably backward and to the left.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward.
- Deactivating a first sensor, preferably a left sensor will control the state of an object in an eighth state, preferably backward and to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will control the state of an object in a fourth state, preferably backward.
- Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will stop control in a fourth state, preferably backward.
- Independently activating a first sensor will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward.
- Deactivating a second sensor, preferably a right sensor will control the state of an object in a fifth state, preferably upward and to the left.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will control the state of an object in a third state, preferably upward.
- Deactivating a first sensor, preferably a left sensor will control the state of an object in a sixth state, preferably upward and to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward.
- Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will stop control in a third state, preferably upward.
- Independently activating a first sensor, preferably a left sensor will control the state of an object in a first state, preferably to the left.
- Deactivating a first sensor, preferably a left sensor will stop control in a first state, preferably to the left.
- Independently activating a second sensor will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably downward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a seventh state, preferably downward and to the left.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably downward.
- Deactivating a first sensor, preferably a left sensor will control the state of an object in an eighth state, preferably downward and to the right.
- Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will control the state of an object in a fourth state, preferably downward.
- Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor will stop control in a fourth state, preferably downward.
- Independently activating a first sensor will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor, preferably a top sensor, of a second set of two sensors will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, of a second set of two sensors will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a third state, preferably forward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward.
- Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a fourth state, preferably backward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor, preferably a top sensor, of a second set of two sensors will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, of a second set of two sensors will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward.
- Deactivating a fourth sensor, preferably a bottom sensor will control the state of an object in an eleventh state, preferably forward and upward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor will control the state of an object in a third state, preferably forward.
- Deactivating a third sensor, preferably a top sensor will control the state of an object in a twelfth state, preferably forward and downward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a third state, preferably forward. Independently activating a third sensor, preferably a top sensor, will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward.
- a fourth sensor Independently activating a fourth sensor, preferably a bottom sensor, will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a fourth sensor, preferably a bottom sensor, will control the state of an object in a thirteenth state, preferably backward and upward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward.
- Deactivating a third sensor, preferably a top sensor will control the state of an object in a fourteenth state, preferably backward and downward.
- Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor will control the state of an object in a fourth state, preferably backward.
- Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor will stop control in a fourth state, preferably backward.
- Independently activating a third sensor will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward.
- any adjustable first sensor preferably a left sensor
- any adjustable second sensor preferably a right sensor
- Activating an adjustable first sensor will control the state of an object.
- Increasing the activation parameters of an adjustable first sensor preferably a left sensor
- Increasing the activation parameters of an adjustable first sensor will increase the rate of control of an object and decreasing the activation parameters of an adjustable first sensor, preferably a left sensor
- Activating an adjustable second sensor preferably a right sensor
- Increasing the activation parameters of an adjustable second sensor preferably a right sensor
- will increase the rate of control of an object and decreasing the activation parameters of an adjustable second sensor, preferably a right sensor will decrease the rate of control of an object.
- the two sensor control invention according to the preferred embodiment and alternative preferred embodiments of the invention, is logically developed, relatively easy to learn and very quick to use.
Abstract
Multiple methods of using only two sensors to control the state of an object in a one dimensional environment, a two dimensional environment or a three dimensional environment. A method of using only two sensors to control the state of an object in a secondary mode and edit data in a third mode. A method of using only two sensors to edit changes. A method of using only two sensors to control the state of an object in graphic arts programs. A method of using only two sensors to control the state of an object in two states, three states, four states, eight states, ten states or fourteen states. A method of using only two sensors to increase or decrease control of an object.
Description
- This application is a continuation of U.S. patent application Ser. No. 10/241,119 filed Sep. 11, 2002.
- This invention relates to a method of control using only two sensors.
- This application is an improvement on the method of control in U.S. Pat. No. 5,993,089 entitled, “8-BIT BINARY CODE FOR USE AS AN 8-DOT BRAILLE ARRANGEMENT AND DATA ENTRY SYSTEM AND METHOD FOR 8-KEY CHORDIC BINARY KEYBOARDS”, in which a copyright and a patent were granted. This application is also an improvement on the invention found in U.S. patent application Ser. No. 10/071,952 filed on Feb. 6th, 2002 entitled, “VIRTUAL KEYBOARD AND CONTROL MEANS”.
- There are numerous well-known, prior art methods of moving using two sensors independently, the best and oldest examples would be an animal pulled plow and the motor driven tractor. With the rapid development of man-machine interfaces for communicating and control, improved methods of movement and control means are becoming increasingly necessary. The main objective of the present invention is to overcome all the deficiencies found in all prior art devices for two sensor control.
- Briefly described, in one of the preferred embodiments of the present invention uses any two binary sensors or two variable controlled sensors to control the state of an object in a first state by activating a first sensor, control the state of an object in a second state by activating a second sensor, control the state of an object in a third state by activating a first sensor and a second sensor simultaneously and control the state of an object in a fourth state by deactivating and reactivating a first sensor and a second sensor simultaneously. Control of any object, robot, cursor, machine, virtual reality environment, etc. in a one dimensional environment or two dimensional environment can easily be obtained using only two sensors. A computer mouse is one preferred embodiment of the invention. The ability to use a two sensor keyboard to reverse the last change made or to reverse the last undo made while using a pointing device in a graphics program, will increase the speed and efficiency in any graphics program or any other two axis cursor pointing program.
- One preferred embodiment of the present invention allows multiple methods of control using only two sensors. Simultaneously activating a first sensor and a second sensor followed by simultaneously deactivating a first sensor and a second sensor will exit a first mode and enter a second mode. Independently activating a first sensor will control the state of an object in a first state. Deactivating a first sensor will stop control in a first state. Independently activating a second sensor will control the state of an object in a second state. Deactivating a second sensor will stop control in a second state. Simultaneously activating a first sensor and a second sensor followed by simultaneously deactivating a first sensor and a second sensor will exit a second mode and enter a third mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor to reverse the last change. Independently activating a second sensor to reverse the last undo.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor will control the state of an object in a first state. Deactivating a first sensor will stop control in a first state. Independently activating a second sensor will control the state of an object in a second state. Deactivating a second sensor will stop control in a second state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Deactivating a second sensor will control the state of an object in a fifth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Deactivating a first sensor will control the state of an object in a sixth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state. Simultaneously deactivating a first sensor and a second sensor will stop control in a third state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Deactivating a second sensor will control the state of an object in a seventh state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Deactivating a first sensor will control the state of an object in an eighth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a fourth state. Simultaneously deactivating a first sensor and a second sensor will stop control in a fourth state. Simultaneously activating a first sensor and a second sensor will control the state of an object in a third state.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor of a second set of two sensors will control the state of an object in a ninth state. Deactivating a third sensor will stop control in a ninth state. Independently activating a fourth sensor of a second set of two sensors will control the state of an object in a tenth state. Deactivating a fourth sensor will stop control in a tenth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state. Deactivating a fourth sensor will control the state of an object in an eleventh state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state. Deactivating a third sensor will control the state of an object in a twelfth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state. Simultaneously deactivating a third sensor and a fourth sensor will stop control in a third state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Deactivating a fourth sensor will control the state of an object in a thirteenth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Deactivating a third sensor will control the state of an object in a fourteenth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a fourth state. Simultaneously deactivating a third sensor and a fourth sensor will stop control in a fourth state. Simultaneously activating a third sensor and a fourth sensor will control the state of an object in a third state.
- Another preferred embodiment of the present invention allows another method of control and rate of control using only two sensors. Using any adjustable sensor will increase or decrease the rate of an object by producing different degrees of activation. Activating an adjustable first sensor will control the state of an object. Increasing the activation parameters of an adjustable first sensor will increase the rate of control of an object and decreasing the activation parameters of an adjustable first sensor will decrease the rate of control of an object. Activating an adjustable second sensor will control the state of an object. Increasing the activation parameters of an adjustable second sensor will increase the rate of control of an object and decreasing the activation parameters of an adjustable second sensor will decrease the rate of control of an object.
- The system and method of the two sensor control invention, according to the preferred embodiment and alternative preferred embodiments of the invention, are logically developed, relatively easy to learn and very quick to use.
- These and other features of the present invention will be more fully understood by reference to the following drawings and the detailed description of the preferred embodiment.
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FIG. 1 . Illustrates one preferred arrangement of a two sensor embodiment found in the disclosed invention. -
FIG. 2 . Illustrates one preferred arrangement of a two sensor embodiment found in the disclosed invention. -
FIG. 3 . Illustrates one preferred arrangement of a horizontal first set of two sensors embodiment combined with a vertical second set of two sensors embodiment positioned on the left, found in the disclosed invention. -
FIG. 4 . Illustrates one preferred arrangement of a horizontal first set of two sensors embodiment combined with a vertical second set of two sensors embodiment positioned on the right, found in the disclosed invention. - In order to more fully understand the invention, during the course of this description the two sensor invention will be labeled as a first sensor and a second sensor, unless a second set of two sensors is added, and will be used to easily identify like elements according to the different figures which illustrate the invention. The preferred embodiment of the invention is shown in
FIGS. 1, 2 , 3 and 4 in the preferred embodiment's simplest binary sensor on/off method form. - One preferred embodiment of the present invention uses any two binary sensors or two variable controlled sensors for control in a first state by activating a first sensor, and in a second state by activating a second sensor. Control of any object, robot, cursor, machine, virtual reality environment, etc. in a one dimensional environment or two dimensional environment can easily be obtained using only two sensors. A computer mouse is one preferred embodiment of the invention. Other examples of two sensor preferred embodiments of the invention are the cursor left and cursor right keys on a standard computer keyboard, the left and right space bar keys on a split space bar computer keyboard, any two keys on a standard computer keyboard, any two keys on any keyboard or data entry device ever produced or will ever be produced. The ability to use a two sensor keyboard to reverse the last change made or to reverse the last undo made while using a pointing device in a graphics program, will increase the speed and efficiency in any graphics program or any other two axis cursor pointing program. Any two binary sensors or two variable controlled sensors includes but is not limited to: accelerometers, biometric sensors, biosensors, flex sensors, micro force sensors, motion sensors, optical sensors, piezoelectric force sensors, position sensors, pressure sensors, temperature sensors, touch sensors, touch screen sensors, contact switch, detector switch, dimmer switch, dual motion switch, electromechanical switch, key switch, membrane switch, pushbutton switch, rocker switch, rotary switch, snap action switch, toggle switch, vertical touch switch, and the like.
- One preferred embodiment of the present invention allows multiple methods of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and enter a third mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and enter a third mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a first mode and enter a second mode. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a second mode and enter a third mode. Independently activating a first sensor, preferably a left sensor, will delete data in a first state, preferably to the left of an object. Deactivating a first sensor, preferably a left sensor, will stop deleting data in a first state, preferably to the left of an object. Independently activating a second sensor, preferably a right sensor, will delete data in a second state, preferably to the right of an object. Deactivating a first sensor, preferably a left sensor, will stop deleting data in a second state, preferably to the right of an object. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, followed by simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will exit a third mode and re-enter a first mode.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, to reverse the last change. Independently activating a second sensor, preferably a right sensor, to reverse the last undo.
- One preferred embodiment of the present invention uses any two binary sensors or two variable controlled sensors to control the state of an object in a first state by activating a third sensor, control the state of an object in a second state by activating a fourth sensor, control the state of an object in a third state by activating a third sensor and a fourth sensor simultaneously and control the state of an object in a fourth state by deactivating and reactivating a third sensor and a fourth sensor simultaneously. A second set of two sensors allows complete control in a three dimensional environment. A computer mouse and two keys on any keyboard are preferred embodiments of the invention. Other examples of two sensor preferred embodiments of the invention are the cursor left and cursor right keys combined with any other two keys on a standard computer keyboard, the left and right space bar keys combined with any other two keys on a split space bar computer keyboard, any two keys combined with any other two keys on a standard computer keyboard, any two keys combined with any other two keys on any keyboard or data entry device ever produced or that will ever be produced.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a fourth state, preferably backward. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object upward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop upward control. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object downward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop downward control. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object upward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a fifth state, preferably forward and to the left. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Deactivating a first sensor, preferably a left sensor, will control the state of an object in a sixth state, preferably forward and to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably forward. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a seventh state, preferably backward and to the left. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a first sensor, preferably a left sensor, will control the state of an object in an eighth state, preferably backward and to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably backward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a fourth state, preferably backward. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a fifth state, preferably upward and to the left. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward. Deactivating a first sensor, preferably a left sensor, will control the state of an object in a sixth state, preferably upward and to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a third state, preferably upward. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably downward. Deactivating a second sensor, preferably a right sensor, will control the state of an object in a seventh state, preferably downward and to the left. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably downward. Deactivating a first sensor, preferably a left sensor, will control the state of an object in an eighth state, preferably downward and to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a fourth state, preferably downward. Simultaneously deactivating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will stop control in a fourth state, preferably downward. Independently activating a first sensor, preferably a left sensor, will control the state of an object in a first state, preferably to the left. Deactivating a first sensor, preferably a left sensor, will stop control in a first state, preferably to the left. Independently activating a second sensor, preferably a right sensor, will control the state of an object in a second state, preferably to the right. Deactivating a second sensor, preferably a right sensor, will stop control in a second state, preferably to the right. Simultaneously activating a first sensor, preferably a left sensor, and a second sensor, preferably a right sensor, will control the state of an object in a third state, preferably upward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor, preferably a top sensor, of a second set of two sensors will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, of a second set of two sensors will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a third state, preferably forward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a fourth state, preferably backward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control using only two sensors. Independently activating a third sensor, preferably a top sensor, of a second set of two sensors will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, of a second set of two sensors will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Deactivating a fourth sensor, preferably a bottom sensor, will control the state of an object in an eleventh state, preferably forward and upward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Deactivating a third sensor, preferably a top sensor, will control the state of an object in a twelfth state, preferably forward and downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a third state, preferably forward. Independently activating a third sensor, preferably a top sensor, will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a fourth sensor, preferably a bottom sensor, will control the state of an object in a thirteenth state, preferably backward and upward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward. Deactivating a third sensor, preferably a top sensor, will control the state of an object in a fourteenth state, preferably backward and downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a fourth state, preferably backward. Simultaneously deactivating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will stop control in a fourth state, preferably backward. Independently activating a third sensor, preferably a top sensor, will control the state of an object in a ninth state, preferably upward. Deactivating a third sensor, preferably a top sensor, will stop control in a ninth state, preferably upward. Independently activating a fourth sensor, preferably a bottom sensor, will control the state of an object in a tenth state, preferably downward. Deactivating a fourth sensor, preferably a bottom sensor, will stop control in a tenth state, preferably downward. Simultaneously activating a third sensor, preferably a top sensor, and a fourth sensor, preferably a bottom sensor, will control the state of an object in a third state, preferably forward.
- Another preferred embodiment of the present invention allows another method of control and rate of control using only two sensors. Using any adjustable first sensor, preferably a left sensor, and any adjustable second sensor, preferably a right sensor, will increase or decrease the speed of an object in a desired state by producing different degrees of activation. Activating an adjustable first sensor, preferably a left sensor, will control the state of an object. Increasing the activation parameters of an adjustable first sensor, preferably a left sensor, will increase the rate of control of an object and decreasing the activation parameters of an adjustable first sensor, preferably a left sensor, will decrease the rate of control of an object. Activating an adjustable second sensor, preferably a right sensor, will control the state of an object. Increasing the activation parameters of an adjustable second sensor, preferably a right sensor, will increase the rate of control of an object and decreasing the activation parameters of an adjustable second sensor, preferably a right sensor, will decrease the rate of control of an object.
- These and other features of the present invention will be more fully understood by referencing the drawings.
- In summary, the two sensor control invention, according to the preferred embodiment and alternative preferred embodiments of the invention, is logically developed, relatively easy to learn and very quick to use.
- While the invention has been described with reference to the preferred embodiment thereof, it will be appreciated by those of ordinary skill in the art that various modifications can be made to the system and method of the invention without departing from the spirit and scope of the invention as a whole.
Claims (25)
1-22. (canceled)
23. A method of using a pair of sensors to control an object comprising the steps of:
a) simultaneously activating a first sensor and a second sensor of said pair of sensors to exit a first mode and enter a second mode;
b) activating said first sensor to control said object in a first state; and
c) activating said second sensor to control said object in a second state;
d) simultaneously activating said first sensor and said second sensor to exit said second mode;
e) wherein the respective modes are entered or exited based on the activation of only the two respective first and second sensors and no other sensors.
24. A method of using a pair of sensors to control an object, in accordance with claim 23 , further comprising the step of simultaneously activating said first sensor and said second sensor to exit said second mode and enter a third mode.
25. A method of using a pair of sensors to control an object, in accordance with claim 23 , further comprising the step of simultaneously activating said first sensor and said second sensor to exit said second mode and re-enter said first mode.
26. A method of using a pair of sensors to control an object, in accordance with claim 23 , further comprising the steps of:
a) activating at least one sensor other than said first sensor or said second sensor of said pair of sensors to exit said second mode and re-enter said first mode;
b) wherein the second mode is entered based on the activation of only the two respective first and second sensors and no other sensors.
27. A method of using a pair of sensors to control an object comprising the steps of:
a) activating a first sensor of said pair of sensors to control an object in a first state; and
b) activating a second sensor of said pair of sensors to control said object in a second state;
c) simultaneously activating said first sensor and said second sensor to exit a first mode and enter a second mode;
d) activating said first sensor to control said object in a third state; and
e) activating said second sensor to control said object in a fourth state;
f) simultaneously activating said first sensor and said second sensor to exit said second mode;
g) wherein the respective modes are entered or exited based on the activation of only the two respective first and second sensors and no other sensors.
28. A method of using a pair of sensors to control an object, in accordance with claim 27 , further comprising the step of simultaneously activating said first sensor and said second sensor to exit said second mode and enter a third mode.
29. A method of using a pair of sensors to control an object, in accordance with claim 27 , further comprising the step of simultaneously activating said first sensor and said second sensor to exit said second mode and re-enter said first mode.
30. A method of using a pair of sensors to control an object, in accordance with claim 27 , further comprising the steps of:
a) activating at least one sensor other than said first sensor or said second sensor of said pair of sensors to exit said second mode and re-enter said first mode;
b) wherein the second mode is entered based on the activation of only the two respective first and second sensors and no other sensors.
31. A method of using a pair of sensors to control an object, in accordance with claim 27 , comprising:
a) activating a left sensor of said pair of sensors to move a cursor to the left; and
b) activating a right sensor of said pair of sensors to move a cursor to the right;
c) simultaneously activating said left sensor and said right sensor to exit a first mode and enter a second mode;
d) activating said left sensor to backspace; and
e) activating said right sensor to delete data;
f) simultaneously activating said left sensor and said right sensor to exit said second mode and enter a third mode;
g) wherein the respective modes are entered or exited based on the activation of only the two respective left and right sensors and no other sensors.
32. A method of using a pair of sensors to control an object, in accordance with claim 27 , comprising:
a) activating a left sensor of said pair of sensors to move a cursor to the left; and
b) activating a right sensor of said pair of sensors to move a cursor to the right;
c) simultaneously activating said left sensor and said right sensor to exit a first mode and enter a second mode;
d) activating said left sensor to backspace; and
e) activating said right sensor to delete data;
f) simultaneously activating said left sensor and said right sensor to exit said second mode and re-enter said first mode;
g) wherein the respective modes are entered or exited based on the activation of only the two respective left and right sensors and no other sensors.
33. A method of using a pair of sensors to control an object, in accordance with claim 27 , comprising:
a) activating a left sensor of said pair of sensors to move a cursor to the left; and
b) activating a right sensor of said pair of sensors to move a cursor to the right;
c) simultaneously activating said left sensor and said right sensor to exit a first mode and enter a second mode;
d) activating said left sensor to backspace; and
e) activating said right sensor to delete data;
f) activating at least one sensor other than said first sensor or said second sensor of said pair of sensors to exit said second mode and re-enter said first mode;
g) wherein the second mode is entered based on the activation of only the two respective first and second sensors and no other sensors.
34. A method of using a pair of sensors to control an object comprising the steps of:
a) exiting a first mode and entering a second mode by activating at least one sensor;
b) activating a first sensor of said pair of sensors to control said object in a first state; and
c) activating a second sensor of said pair of sensors to control said object in a second state;
d) wherein said first and said second sensors produce standard functions in a first mode and produce secondary functions in a second mode.
35. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the step of exiting a first mode and entering a program by activating at least one sensor.
36. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the step of exiting a first mode and entering a program by double activation of at least one sensor.
37. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the step of exiting a first mode and entering a graphics editing mode by activating at least one sensor.
38. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the steps of:
a) activating a left sensor of said pair of sensors to control said object in a first state; and
b) activating a right sensor of said pair of sensors to control said object in a second state.
39. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the steps of:
a) activating a first sensor of said pair of sensors to reverse a last change; and
b) activating a second sensor of said pair of sensors to reverse a last undo.
40. A method of using a pair of sensors to control an object, in accordance with claim 34 , further comprising the steps of:
a) activating a cursor left sensor of said pair of sensors to reverse a last change; and
b) activating a cursor right sensor of said pair of sensors to reverse a last undo.
41. A method of using two pairs of sensors to control an object comprising the steps of:
a) activating a first sensor of a first pair of sensors to control said object in a first state; and
b)
activating a second sensor of said first pair of sensors to control said object in a second state;
c) activating a first sensor of a second pair of sensors to control said object in a third state; and
d) activating a second sensor of said second pair of sensors to control said object in a fourth state;
e) simultaneously activating said first sensor and said second sensor of said first pair of sensors to exit a first mode and enter a second mode;
f) activating said first sensor of said first pair of sensors to control said object in a fifth state; and
g) activating said second sensor of said first pair of sensors to control said object in a sixth state;
h) simultaneously activating said first sensor and said second sensor of said first pair of sensors to exit said second mode;
i) wherein the respective modes are entered or exited based on the activation of only the two respective first and second sensors of said first pair of sensors and no other sensors.
42. A method of using two pairs of sensors to control an object, in accordance with claim 41 , further comprising the step of simultaneously activating said first sensor and said second sensor of said first pair of sensors to exit said second mode and enter a third mode.
43. A method of using two pairs of sensors to control an object, in accordance with claim 41 , further comprising the step of simultaneously activating said first sensor and said second sensor of said first pair of sensors to exit said second mode and re-enter said first mode.
44. A method of using two pairs of sensors to control an object, in accordance with claim 41 , further comprising the steps of:
a) activating at least one sensor other than said two pairs of sensors to exit said second mode and re-enter said first mode;
b) wherein the second mode is entered based on the activation of only the two respective first and second sensors of said first pair of sensors and no other sensors.
45. A method of using two pairs of sensors to control an object, in accordance with claim 41 , further comprising the steps of:
a) activating an up sensor of a first pair of sensors to move said object up; and
b) activating a down sensor of said first pair of sensors to move said object down;
c) activating a left sensor of a second pair of sensors to move said object left; and
d) activating a right sensor of said second pair of sensors to move said object right;
e) simultaneously activating said up sensor and said down sensor of said first pair of sensors to exit a first mode and enter a second mode;
f) activating said up sensor of said first pair of sensors to move said object forward; and
g) activating said down sensor of said first pair of sensors to move said object backward;
h) simultaneously activating said up sensor and said down sensor of said first pair of sensors to exit said second mode and re-enter said first mode;
I) wherein the respective modes are entered or exited based on the activation of only the two respective up and down sensors of said first pair of sensors and no other sensors.
46. A method of using two pairs of sensors to control an object, in accordance with claim 41 , further comprising the steps of:
a) activating an up sensor of a first pair of sensors to move said object forward; and
b) activating a down sensor of said first pair of sensors to move said object backward;
c) activating a left sensor of a second pair of sensors to move said object left; and
d) activating a right sensor of said second pair of sensors to move said object right;
e) simultaneously activating said up sensor and said down sensor of said first pair of sensors to exit a first mode and enter a second mode;
f) activating said up sensor of said first pair of sensors to move said object up; and
g) activating said down sensor of said first pair of sensors to move said object down;
h) simultaneously activating said up sensor and said down sensor of said first pair of sensors to exit said second mode and re-enter said first mode;
I) wherein the respective modes are entered or exited based on the activation of only the two respective up and down sensors of said first pair of sensors and no other sensors.
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US12/348,604 US20090312847A1 (en) | 2002-09-11 | 2009-01-05 | Two sensor control |
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US20080306614A1 (en) * | 2007-06-07 | 2008-12-11 | Burrell Iv James W | Four sensor control |
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US20090312847A1 (en) * | 2002-09-11 | 2009-12-17 | Burrell Iv James W | Two sensor control |
US9278254B2 (en) * | 2004-08-13 | 2016-03-08 | Wilfred Washington Holness | Apparatus for isometric and incremental muscle contractions |
US20060209031A1 (en) * | 2005-03-18 | 2006-09-21 | Burrell James W Iv | Hand held communications computer and keyboard |
KR20090054755A (en) * | 2007-11-27 | 2009-06-01 | 삼성전자주식회사 | Touch pad having plate for blocking electromagnetic interference |
CN106907567B (en) * | 2017-03-15 | 2023-09-22 | 宾科精密部件(中国)有限公司 | Profile reinforced connection structural member |
CN110989350B (en) * | 2019-12-11 | 2021-08-31 | 安徽理工大学 | Method and device for realizing pose optimization of underground mobile robot based on membrane calculation |
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Also Published As
Publication number | Publication date |
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US7160042B2 (en) | 2007-01-09 |
US20040143348A1 (en) | 2004-07-22 |
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