JPS63186687A - Body motion controller for toy system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention]

FIELD OF THE INVENTION The present invention relates to remote control toy systems. BACKGROUND OF THE INVENTION Known remote control toy systems generally include:
Command sig-nals to small toys such as cars, boats, airplanes, or robots.
) to provide a hand-held radio transmitter (hand-held
radio transmiLLer). Examples of such systems are Takalo's US Pat. No. 3,686.447 (1972) and Licites' US Pat. No. 3,1378.521.
(1975). The transmitter is usually equipped with an operating lever or set of push buttons to enable the child to activate the toy in a variety of ways, including movement in various directions, flashing lights, or a horn. ing. Depending on the number of control functions provided by the system, operation of the transmitter requires the child to practice a certain level of manual dexterity in order to fully understand the capabilities of the various toys. The level of manual dexterity required can limit a child's full understanding of the toy system. SUMMARY OF THE INVENTION Accordingly, the main object of the present invention is to provide a new and simplified method for operator control of remote control toy systems, such as computer games and remotely controlled stationary devices. That's true. This method eliminates the need for manual dexterity exhibited by prior art remote control toy systems. According to the invention, a command signal (command 5i
H-nal) generating means, and a toy object comprising receiver means responsive to the command signal;
and means for operating the toy in accordance with the response of the receiver means located within the toy body, the remote control toy system being electrically coupled to the command generating means and configured to operate the toy according to the movement of the body. An improvement in the means for generating commands is provided, characterized in that it includes a controller attached to the body for varying the operation of the command generating means. controller means attached to the body (body-mo
unted controller means) is
In conjunction with a transmitter, it provides a new and different way to control the operation of a variety of small remote control toys. Here, the transmitter is configured to transmit multiple frequencies (mu
lti-frequency transmission
n), frequency or time division, pulse connection time, sequential transmission of specific frequencies (sequential trans
mission), infrared transmission
transmission) or hard-wired remote connect
It provides command signals based on any of a variety of techniques including In a preferred embodiment, the body-mounted controller means includes a ball switch, the head-mounted ball switch having a ``solid spherical ball'' housed within a small box-like enclosure that is attached to the wristband. The enclosure has at least one contact device arranged therein, the device comprising a movable spring plate contact.
including. This spring plate contact is a stationary contact due to the movement of the ball caused by the movement of the head.
act) or away from the stationary contact. The ball switch may include several such contact devices on different sides inside the enclosure. The contact device is connected to its circuit.
(try) or electrically coupled to the transmitter to provide on-off operation of the portion. In another embodiment, the body-mounted controller means includes a combination of a plurality of mercury switches attached to a head-mounted band and arranged to sense head movements in different directions, and transmit Provides on-off operation to the machine circuit. In yet another embodiment, the body-mounted controller includes a variable resistance device consisting of two small variable resistors mounted within an enclosure attached to the head-mounted wristband. The mounting of the variable resistors is carried out in such a way that each variable resistor has a variable resistor adjustment screw parallel to one of the two vertical axes of rotation. Each adjustment screw may have a small weight suspended from it, or alternatively, one adjustment screw may be attached to a suspension arm fixed within the enclosure and the other adjustment screw suspended from it. With the weight lowered, two small variable resistors are attached to each other, and by the movement of the head the adjustment screw is turned while the weight attempts to maintain a stationary position, part of the circuit of the transmitter. Provides variable ti resistance. In yet other embodiments, a body-mounted controller has a liquid-filled variable resistor, the variable resistor having an electrically conductive liquid sealed within a glass envelope, and wherein the variable resistor has an electrically conductive liquid sealed within a glass envelope; The resistive elements are spaced apart from each other. The variable resistor is attached to the head-mounted band and the liquid acts as an electrical bridge between the parts of the resistive element so that it provides varying resistance to the transmitter circuit according to the movement of the head. do. Other objects, features and advantages of the invention will become apparent from the following description.

[Brief explanation of the drawing]

For a better understanding of the invention with respect to its embodiments, reference is made to the attached figures. In the drawings, FIG. 1 is a diagram of a preferred embodiment of the invention featuring a ball switch in a remote control toy system combination. FIG. 2 is an illustration of another embodiment of the invention featuring a two-axis variable resistor for use in the system combination of FIG. 3 and 4 are top and side view illustrations, respectively, of yet another embodiment of the invention featuring a liquid-filled variable resistor for use in the system combination of FIG. 1. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring now to FIG. 1, there is shown a diagram of a preferred embodiment of the body-mounted controller of the present invention featuring a ball switch 10 in a remote control toy system combination. . The ball switch 10 is a control device 11
For example, the toy system is shown electrically connected via a plurality of interconnect lines, generally indicated by the reference numeral 12, within the toy system to a portion of the toy system that is coupled to a wireless transmitter 13. The part of the toy system which is here coupled with said radio transmitter 13 is, for example, capable of generating a command signal which causes a response in the toy having a receiver designated by reference numeral 14. As further discussed herein, the ball switch 10 is adaptable for attachment to a body part, such as the head of an operator of a toy system, and provides a novel method of control. Ball switch 10 includes a box-shaped enclosure 15 shown in plan view, which includes a side wall 17 extending vertically between a top wall (not shown in cutaway view) and a bottom wall 23. 18. Each of the six walls 17-22 with an enclosed space 16 defined by 20 and 22 is made of electrically insulating material and has electrical switch contacts mounted therein extending through each car. Each pair A, B
, C and D. Each pair of contacts A-D is similarly arranged, and as shown for contact A, each pair of contacts A-D has an eaf contact
) 24 and a stationary contact, with contact pair A normally open (N
O) switch or normally closed (NC) switch. A portion of each of the movable and stationary contacts 24 and 26 is connected to the wall 17 for connection to an external circuit.
It penetrates and protrudes. A generally spherical ball 28 is positioned within the enclosed space 16, and the ball is free within the boundaries of the area defined by the movable contact 24 of each of the plurality of contact pairs A-D. It has a diameter selected to allow movement. Ball 28 is generally made of a rigid material, and the material may be insulating or electrically conductive. The weight of the ball 28 is such that no matter when it rolls toward any of the plurality of contacts A to D, the weight of the ball 28 is
moving the movable spring plate contact 24 towards or away from its half stationary contact 26 so as to perform a 5w1tchooperation);
This is to overcome the inherent spring-like stiffness of the movable leaf spring contactor 24. Therefore, each of the plurality of contact pairs A to D is based on the movement of the ball 28 within the space 16.
The ball 28 can also be suspended within the enclosure 15 to provide this closing or opening switching action of the plurality of contact pairs A-D. The control device 11 can be adapted for example to be mounted on the operator's head of a remote control toy system. This can be done in any of several ways. One possibility is The head mount to be worn on top is to attach a wristband (not shown) to the bottom wall 23 of the enclosure 15.Another possibility is that the head mount is placed on a wristband (not shown) on the bottom wall 23 of the enclosure 15. The side walls of the enclosure 15 are then attached to the front portion of the headband.It is also possible to adapt the transmitter 13 to be positioned above the headband. Another possible mounting of the control device 11 on the body is to use an arm or leg band with a ball switch 10 and a transmitter 13 attached to it.A head-mounted control device 11 In operations using
The ball switch 10 determines the direction of the head.
(on) provides a new method of controlling the operation of the control device 11. When the direction of the head changes, ball 28 becomes circle 15.
rolling around within the contactor, thereby displacing one or more of the plurality of contact pairs A-D during the closing or opening switching operation. This then connects the interconnect line 12
The electrical operation of the circuitry of the control unit W11 is performed according to the selected electrical design established by the controller W11. When the control device 11 is, for example, a radio transmitter 13, its design:
Each of the contact pairs A to D may perform on-off operation of the transmitter 13. If the toy system is a remotely controlled vehicle, certain responses, such as a right or left turn, can alternatively be designed as a result of the closure of certain contact pairs. There are at least nine positions of the ball 28 that can be obtained from changes in the orientation of the head. These positions are four associated with each of the plurality of contact pairs A-D, four associated with the corner positions of the ball 28 that simultaneously leans on two of the plurality of contact pairs A-D, and four associated with the contact A-D. ~D is the neutral position of one of the balls 28 in the center of the enclosure such that none of them close. In the case of the metal ball 28, when the metal ball is in a corner position, the ball 28 prevents a short circuit 8 between adjacent corners.
The inwardly facing side of the movable leaf spring contact 24 may be coated with an electrically insulating material. Otherwise, the electrical circuit design
This possibility will be taken into account as one of the operational changes. - if the ball switch 10 is designed to use a metal ball,
The enclosed space 16 can be provided with one wall of the enclosure 15 having a conductive coating that acts as one side of the switch. The metal ball 28 itself provides a bridge to the other side of the switch as the ball rolls toward any one of contact pairs A-D. Another embodiment of the body-mounted controller of the present invention is a combination of multiple mercury switches arranged to provide on-off operation of the transmitter 13 similar to the on-off operation provided by the ball switch 10. It is characterized by Referring to FIG. 2, another embodiment of the present invention is shown featuring a two-axis variable resistor for use in the toy system combination shown in FIG. The structure 30 includes a pair of variable resistors 32 and 34 that can be electrically connected to a control device (FIG. 1) via a set of pin connectors 36 and 38. As further discussed herein, structure 30 can be adapted for head mounting. The arrangement of variable resistors 32 and 34 is also such that it allows for a novel method of operator control of the toy system with respect to head orientation. Each of variable resistors 32 and 34 is preferably of the small box housing type used in printed circuit board designs such as those sold under the trademark Bourns. Each resistor 32 and 34
Typically, wipers (lli
have respective adjustment screws 40 and 42 for adjusting its resistance by movement of per). The resistors 32 and 34 are arranged in a suitable manner on one side of their housing so that their respective adjustment screws 40 and 42 are 90 degrees apart from each other.
It is installed so that it is located at ゜. Resistors 32 and 34
The joint assembly is suspended from an adjustment screw 40 fixed to a horizontal suspension arm 44. The suspension 11!1f44 extends from the flange 46 at one end and is integrated therewith. At this end flange 46, the suspension arm is connected to a mounting surface 50 by means of mounting screws mounted in the wall 51. wall 5
1 is the negative side of a box-like enclosure (not shown) for the entire structure 30. Connecting arm 5 attached to adjustment screw 42
2, and there is a weight 54 vertically suspended from the connecting arm 52. Attachment surface 50 serves as a means for attaching the entire structure 30 to a head attachment band (not shown) located on the forehead. When the structure 30 is placed on the forehead, movement of the operator's head affects the orientation of the resistors 32 and 34, which are free to rotate about their respective adjustment screws 40 and 42.
n), the adjustment screw 42 tends to be fixed in position by the balance provided by the weight 54, so that changes in the orientation of the resistors 32 and 34 are then controlled via the pin sets 36 and 38. This will change the resistance provided by each of both resistors to the circuit of device 12. The variable resistance provided by resistors 32 and 34 may serve to vary the operation of a portion of the circuit of control device 12, which may be radio transmitter 13 as described above. The deformation is performed using a differential resistor so that the operation is similar to that provided by the ball switch 10.
ance) can be designed as a trigger operation based on the measurement of . In this case, head orientation provides a new way to control the operation of the remote control toy system. Referring now to FIGS. 3 and 4, there are shown top and side views, respectively, of a liquid-filled variable resistance structure 56 for use in the toy system combination of FIG. 1. A hermetically sealed envelope 58 of electrically insulating material, such as glass, is provided to surround the plurality of electrically resistive elements J, L, M and N. Each electrically resistive element is made of powdered carbon composite material (pow
- made of a resistive material such as carbon composite. The sealed envelope 58 is attached to the substrate 5
Mounted on top of 9. A plurality of resistive elements J-N are secured inside the jacket 58 and each shaped to match the curvature of the jacket 58 at their respective locations. Each one of the plurality of resistive elements J-N has a respective individual bin connector 60, 62, 64 and 68, each bin connector having a respective connection point.
protruding through a sealed envelope 58 to provide a rupture point). A quantity of an electrically conductive liquid 70, such as mercury, is contained within a sealed envelope 58 such that it is in electrical contact with portions of the plurality of resistive elements J-N. The variable resistance structure 56 of FIGS. 3 and 4 can be attached to a head mount (not shown) for use with the toy system of FIG. When so mounted, changes in the orientation of the head are caused by J~ within the mantle 58.
The movable liquid has the effect of bridging two adjacent resistive element portions of the N resistive elements in various ways. Bridging any two resistive elements (d
egree) also changes the total resistance presented between their respective bin connectors. As before, the variable resistance obtained from the variable resistor structure 56 serves to vary or trigger the operation of the interconnected circuit parts in the control device 11. The control device 11 transmits 1% of wireless transmission (radio jrans++1tter) as described above.
The head orientation thus provides a novel way to control the operation of a remotely controlled toy system. Thus, in accordance with the present invention, a body-mounted controller is provided for use in conjunction with known toy systems, such as wirelessly remotely controlled automobiles. Various embodiments may be contemplated to operate with such a system to take full advantage of all available control operations through novel control methods. It is also possible to combine and interconnect the controllers that can be attached to the body mentioned above. Although the invention has been described with respect to particular embodiments, it is to be understood that the description is given by way of example only and is not intended as a limitation on the scope of the invention as claimed. It is.

[Brief explanation of the drawing]

FIG. 1 is a partially cut away plan view of a preferred embodiment of the invention featuring a ball switch in a remote control toy system combination; FIG. 2 is a two-axis variable resistor for use in the system combination of FIG. FIG. 3 is a perspective view of yet another embodiment of the invention featuring a liquid-filled variable resistor for use in the system combination of FIG. 1, respectively. FIG. 2 is a diagram and a side view. 10...ball switch 11...interconnection line 13...wireless transmitter 14...receiver 15...enclosure 16...space 17.18.20.22...side wall 23... Bottom wall 24...Movable spring fine contact 26...Stationary contacts A, B, C, D...Electrical switching contact 28...Ball 30...Two-axis variable resistor body 32. 34...Variable resistor 36.38...Bin connector group 40.42...Adjusting screw 44...Horizontal suspension arm 46...Plunge 50...Mounting on surface 51...Wall 52... ...Connection arm 54...Weight 56...Liquid-filled variable resistor structure 59...5 jackets...Substrate

Claims (13)

[Claims] (1) A combination of a remote control toy system including a command signal generating means, a toy body including a receiver means responsive to the command signal, and a means for operating the toy in accordance with the response of the receiver means, The command signal generating means is electrically coupled to the command generating means and includes a controller attached to the body for changing the operation of the command signal generating means according to the movement of the body. A combination of remote control toy systems. (2) the body-mounted controller means comprises a ball switch, the ball switch comprising a solid spherical ball housed within a box-like enclosure attached to the head by a mounting band; and at least one of the walls of the enclosure has at least one contacting device mounted therein, the contacting device performing a switching operation relative to a stationary contact by movement of a ball due to movement of the head. A combination toy system according to claim 1, characterized in that it includes one movable spring plate contact. 3. The ball switch of claim 2 further comprising a plurality of contact devices, each contact device being coupled to one wall of the enclosure. (4) The contact device according to claim 2 or 3, wherein the contact device is interconnected with a radio transmitter to provide on-off operation of the circuit or part thereof. The ball switch described in item 1. (5) The controller means attached to the body includes at least one mercury switch arranged to switch the command signal generating means in accordance with the movement of the body. A combination of toy systems according to scope 1. (6) said body-mounted controller means is a variable resistor assembly consisting of two small variable resistors attached to each other and mounted within said enclosure attached to a head-mounted band; The variable resistors are mounted such that each variable resistor has a variable resistor adjustment screw parallel to one of the two vertical axes of rotation, and the variable resistors are mounted such that each variable resistor has a variable resistor adjustment screw parallel to one of the two vertical rotational axes, One of the adjusting screws is attached to a hanging arm fixed within the enclosure, and the other is attached to a weight suspended therefrom, such that each of the variable resistors provides a variable resistance to the command signal generating means. The first claim characterized in that
A combination of toy systems described in Section. (7) the body-mounted controller comprises a liquid-filled variable resistor attached to a head-mounted band, the resistor being an electrically conductive liquid sealed within a glass envelope; and resistive elements are spaced apart from each other within the jacket, and the liquid is configured to provide a variable resistance to the command signal generating means in accordance with movement of the head. A toy system combination according to claim 1, characterized in that it acts as an electrical bridge between portions of the resistive element. (8) A toy body including a command signal generating means and a receiver means responsive to the command signal, and within the toy body,
and means for operating a toy in accordance with a response of the receiver means, the method comprising: varying the operation of the command signal generating means in accordance with body movement; , a body electrically coupled to the command signal generating means;
CLAIMS 1. A method of operating a combination of remote control toy systems, comprising the step of reorienting a controller means. (9) The method of operating a combination of a remote control toy system according to claim 8, wherein the direction of the body movement controller means is changed by movement of the head. (10) The method of operating a combined remote control toy system according to claim 8, wherein the direction of the body motion controller means is changed by the movement of an arm. (11) The method of operating a combination of a remote control toy system according to claim 8, wherein the direction of the body movement controller means is changed by the movement of the feet. (12) A body-mounted controller for use with a remote control toy system substantially as herein described by way of example and with reference to the drawings. (13) A method of operating a remote control toy system as herein described by way of example and with reference to the drawings.