Abstract:
An improved vehicle throttle control mechanism in which a member captures the movement of an operators thumb beneath the underside of the said vehicle&#39;s handlebar. The operator is able to actuate the throttle without removing his thumb or the palm of his hand from contact with the handle bar. Other elements of the control system reduce operator fatigue and improve vehicle control.

Description:
BACKGROUND OF THE INVENTION 
   (1) Field of the Invention 
   This invention relates to the improvements in the engine throttling of vehicles, particularly motorcycle, snowmobiles, and all terrain vehicles which are steered using handlebars and whose engine output is regulated by a thumb throttle control. 
   (2) Description of Related Art 
   Thumb throttles controls are standard equipment on nearly all snowmobiles and the majority of all terrain vehicles. Thumb throttle controls currently in use capture the motion of the thumb moving towards the handle bar which limits the ability of an operator to grip the handlebar or perform other functions with their hand while operating the thumb throttle controller. The advantage of this design is that the thumb is being pulled towards lever by the whole hand so the operator can overcome the resistance of a strong throttle return spring deal well with the fatigue induced by constantly having to resist the force of the throttle return spring. On vehicles equipped with sliding valve throttle bodies operator&#39;s hands receive additional fatigue trying to resist the movement of the sliding valve every time the vehicle is jostled around as it strikes any kind of bump. This phenomenon also reduces both vehicle control and forces the use of overly heavy return springs to reduce the tendency of the throttle blade to be bounced open. 
   U.S. Pat. No. 7,086,379 details the use of an secondary electronically controlled throttle body to improve the performance of a motorcycle equipped with a traditional twist grip throttle controller coupled directly to the primary throttle body by a traditional wire cable. 
   U.S. Pat. No. 7,010,955 describes the use of a throttle by wire throttle control setup on a motorcycle using data taken from a rotating handlebar grip. No mention is made of the use of any kind of sliding or hinging throttling member. 
   U.S. Pat. Nos. 6,889,654 and 6,699,085 describe how data taken from a finger actuated lever on the handlebar of a personal watercraft can be used to control the throttling of the watercraft&#39;s engine. Mention is made of using this throttling device on other vehicles. The throttle control device cited in the patent is unlike my thumb throttle device in that it consists of a lever mounted in front of the handlebar. The lever is pulled toward the handlebar by the index finger. No mention is made of a throttle control using a sliding member or of a thumb throttle control. The advantage of such a system is cited as being the ability to reduce the amount of return spring necessary to move the throttling lever to its rest position. No mention is made of reducing rider fatigue by decoupling the throttle control lever from the reciprocating mass in the engine&#39;s throttle body. 
   U.S. Pat. No. 5,775,167 describes the use of an additional throttle lever in conjunction with a traditional thumb throttle. This additional throttle is actuated by the index finger in a manner similar to the throttles employed on some personal watercraft and depicted in U.S. Pat. Nos. 6,889,654 and 6,699,085. No mention is made of improving thumb throttle performance using any of the techniques detailed in my claims. 
   U.S. Pat. No. 6,658,965 details the design of a thumb actuated throttle which rotates around the handlebar mimicking the motion of a traditional twist grip throttle controller. 
   U.S. Pat. No. 4,899,610 details the use of a thumb throttle, which pivots about two points so that rider fatigue is reduced by altering the mechanical advantage of the mechanism at different throttle openings. The disadvantage of this approach is a loss of throttle control. 
   SUMMARY OF THE INVENTION 
   The prior art designs of thumb throttle controls have many flaws that have restricted their use to snowmobiles, all terrain vehicles, and some watercraft. The use of thumb throttle controls on motorcycles is very rare and their use is typically by riders who as a result of an injury cannot properly operate a twist throttle. All designs that I am aware of force the operator&#39;s thumb to loose contact with the handlebar while the throttle is being actuated. This makes it difficult for the operator to hold onto the handlebar during harsh decelerations or impacts. Impacts sometimes result in operators fracturing their thumbs. This new thumb throttle controller concept allows the heel of the operators thumb and his palm to remain in constant contact with the handlebar so the operator is unrestricted in his ability to apply the brakes regardless of whether the throttle is being regulated. Since the outstretched thumb is not being thrust towards the throttle lever, in the event of an accident, injury to the thumb or inadvertent actuation of the throttle are unlikely with my improved design. With this design, the motion of the thumb moving across the underside of the handle bar is captured by a moving member that can hinge about a point in the vicinity of the handlebar, follow a sliding path, or move along a path generated by a mechanical linkage composed of two or more members. 
   Since this new thumb throttle controller can be actuated without removing ones hand from the handlebar, the remaining fingers are free to easily apply the front brake lever simultaneously while actuating the throttle. This is a unique advantage on motorcycles and all terrain vehicles because it allows the operators to us the front brake to reduce weight on the vehicles rear wheel or wheels so that an excessive amount of throttle can be used to break the rear wheel or wheels free. The vehicle can than be aggressively steered by using the throttle to keep the rear wheels spinning faster than the road surface to induce controlled over steer. 
   The use of thumb throttles on motorcycle over conventional twist grip throttle controls is that when a motorcycle is equipped with a thumb throttle controller of my design the throttle can be controlled without changing the relationship between the palm of the hand and the handlebar. As such a rider can easily modulate the throttle while shifting his body weight around the motorcycle, or steering the motorcycle and be confident that these motions will not be translated into an unwanted addition or reduction in engine output. When using a motorcycle with a traditional twist grip throttle controller it is difficult to maintain steady throttle control whenever your arm moves in relation to the handlebar. This inherent design flaw of twist throttles becomes painfully apparent when road-racing motorcycles go into high speed oscillations. During these episodes the handlebars are flung wildly from side to side causing the rider is inadvertently add and remove throttle in synchrony with the motion of the handlebars. The addition and subtraction of thrust to the motorcycle drives the oscillation which resulting in a complete loss of control over the motorcycle. Conventional thumb throttle designs make it difficult for a rider operating the thumb throttle to hold onto the motorcycle while braking. Without such control aggressive maneuvers such as Scandinavian flicks are difficult or impossible to perform on motorcycles. 
   While operating a traditional vehicle equipped with a thumb throttle, an operator&#39;s thumb is fatigued both by having to overcome the static force exerted by the throttle&#39;s return spring, and by having to counter the dynamic forces that are applied to the sliding throttle valve when the vehicle strikes and obstacle. Throttle return springs must be sufficiently strong enough to not only close the throttle when the thumb throttle controller is released, but also have sufficient tension to prevent the throttle valve from bouncing off its seat when the vehicle strikes an impact. Essentially, sufficient force must be applied to the sliding valve by either the throttle return spring when in the closed position, or by the operators thumb when in an opened position to accelerate said valve so that its position relative to the vehicle does not change when the vehicle is accelerated upward by an impact. Should the rider or spring be unable to apply sufficient force to accelerate the sliding throttle valve in harmony with the vehicle, there will be an inadvertent change in engine output and ultimately vehicle control. 
   By counterbalancing the sliding throttle valve with an appropriate mass or masses so that when it is moved a proportional amount of total mass is moved in an opposing direction, fatigue to the rider can be significantly reduced and vehicle control can be improved. If the throttle valve is properly coupled to an appropriate amount of mass moving in an opposing direction, the throttle valve&#39;s position in the slide will not be affected when the vehicle strikes a bump. Consequently a lighter return spring can be implemented, as there will no longer be any tendency for the throttle valve to bounce off its seat. Fatigue to the operator&#39;s hands will be reduced, as they will no longer be straining to hold the throttle against an overly strong return spring. Rider fatigue attributed to the dynamic effects of having to hold the throttle slide valve open when striking obstacles are completely eliminated. The counterbalancing mass or masses need not equal the mass of the sliding throttle valve. Provided that the ratios of mass movement to throttle slide movement is linear, masses heavier, or lighter than the sliding throttle valve can be moved appropriate amounts in directions opposing the motion of the sliding throttle valve. The masses can be moved in directions opposite to the throttle blade by a variety of mechanisms including levers, hydraulic cylinders, gears and gear racks, belt drives, chain drives, or by tensioned cables. 
   In applications where there is insufficient room in the vicinity of the sliding throttle valve to couple the balancing mass and the mechanism which couples it to the sliding throttle valve, a separate mechanism can be used to balance the sliding throttle valve while still using a conventional thin cable to pull the sliding throttle valve open. This is achieved by using a combination of an additional mass that is able to move in a direction opposite to the motion of the throttle valve slide. The motion of this additional mass and the sliding throttle valve must both be countered by sufficiently strong return springs to maintain tension in the cable, belt, or chain that couples them together. While these two return springs oppose one another, in order for the throttle to return to its closed position and not some arbitrary partially open condition when the throttle controller is released, a third spring coupled to a falling rate generating mechanism must be incorporated into the mechanism to close the throttle. 
   There are many advantages to using an electronic sensor to capture the position of the vehicle&#39;s throttle controller and to use that information to control an actuator that opens and closes the throttle. A return spring built directly into the throttle controller can be designed with much less initial preload because, unlike a tradition return spring it doesn&#39;t not need to generate sufficient force to actually close the throttle and overcome the inherent friction in the cable or hydraulic system which couples the throttle controller to the throttle. Where a sliding valve type throttling valve is in use, the thumb is no longer has to exert additional force to keep the throttle blade open every time the vehicle strikes a bump. The relationship between throttle controller and the actual opening of the throttle can be tailored to improve drivability or to suit particular riding terrain. A microprocessor can take into consideration what gear the motorcycle is in, that the engine being controlled has a nonlinear torque curve, the current atmospheric conditions, rider ability, wheel speed sensor data to determine vehicle traction, or even what rpm the engine is operating at. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The following drawing will help to describe by example this invention: 
       FIG. 1  shows an overhead view of my thumb throttle actuator mounted to a handlebar 
       FIG. 2  shows an isometric exploded view of the thumb throttle actuator mounted to a handlebar as shown in  FIG. 1 . 
       FIG. 3  shows a side view of an engine inlet air restrictor fitted with a counterbalanced throttle blade. 
       FIG. 4  shows an alternative method of counterbalancing the mass of the slide valve in an engine inlet air restrictor. 
       FIG. 5  shows an alternative design of the thumb throttle actuator with a build in electrical rheostat mounted to a handlebar. 
       FIG. 6  shows an engine inlet air restrictor, which has been retrofitted with a stepper motor and an angular position sensor. 
       FIG. 7  shows a side view of a motorcycle retrofitted with a thumb throttle actuator and a engine air inlet restrictor with a counterbalanced throttle blade. 
       FIG. 8  shows a top view of a motorcycle fitted with an thumb throttle actuator. 
   

   DRAWINGS—REFERENCE NUMERALS 
   DETAILED DESCRIPTION 
   FIGS.  1  and  2 —Preferred Embodiment 
   A preferred embodiment of the thumb throttle control is illustrated in  FIG. 1 . (top view) and  FIG. 2 . (exploded isometric view). The thumb throttle control as shown in  FIG. 1 . depicts in solid lines the most critical parts of the mechanism when it is at rest. One end of the mount  12  attaches to the rotating member  8 , via a pivot  11 , while the other end of the mount secures the device to the vehicle&#39;s handlebar  16 . The rotating member is situated in such a manner that the end furthest from it&#39;s center of rotation is in the vicinity of the handlebar. The throttle cable  14  is attached to the rotating member  8  at a location between the point on the rotating member  8  closest to the handlebar  16 , and the pivot  11 . The throttle cable  14  runs inside the throttle cable sheath  15  that is affixed to the mount  12 . The rotating member  8  is rotated from it rest position which is depicted in solid lines to a second position as shown by the dashed line by the users thumb which rest against the rotating member  1  on the portion of the member which is in close proximity to the handlebar. The rotating member pulls on the throttle cable  14  causing the throttle cable  14  to shift inside of the throttle cable sheath  15  because the throttle cable sheath is affixed to the mount  12 . 
   An exploded isometric view of the thumb throttle control is shown in  FIG. 2 . Note the addition of several additional parts including the throttle cable clamp  9  and the throttle cable clamp bolt  10  that secure the throttle cable  14  to the Rotating Member  8 . A cable length adjuster  13  attaches the throttle cable sheath  15  to the mount  12 . Adjusting the depth that it threads into the mount  12  alters the relationship between the throttle cable  14  and the throttle sheath so that the thumb throttle controllers can be properly synchronized to the engine&#39;s air inlet restrictor or restrictors. To prevent the throttle from being inadvertently opened when the throttle cable sheath  15  is pulled out of the cable length adjuster  13  some method must be employed to hold the two parts together at all times. A throttle return stop  17  determines the rest position of the rotating member  8  in relation to the mount  12 . 
   The thumb throttle controller depicted in  FIG. 1 . and  FIG. 2 . would be affixed to the vehicle&#39;s right handlebar. The operator would grasp the handlebar to the right of the mount  12  with their thumb positioned below the handlebar and their remaining fingers on top of the bar and either gripping the bar or the brake lever. With their hand in it&#39;s proper position their thumb is in contact with both the working surface  19  of the rotating member  8  and the underside of the handlebar  16 . By sliding their thumb towards the end of the handlebar and away from the mount they cause the rotating member  8  to rotate around the pivot  11 . The throttle cable  14  is thus pulled causing a shift in the relationship between it and the throttle cable sheath  15 . This shift in the relationship of the throttle cable  14  to the throttle cable sheath  15  is transmitted to the air inlet restrictor, which regulates the engine&#39;s power output. 
   FIG.  3 .—Additional Component 
   A possible embodiment of an engine air inlet restrictor whose throttle blade is counterbalanced by a suitable mass is shown in illustration  FIG. 3 . Said engine air inlet restrictor consists of a throttle body  29  through which air or a mixture of air and fuel can pass when the throttle blade  30  is moved from its rest position as shown. The return spring  28  holds the throttle blade in a closed position until sufficient tension is place on the throttle cable  26  to overcome the force exerted on the throttle blade  30  by the return spring  28 . The throttle cable is connected to the thumb throttle actuator by the throttle cable  26  and the throttle cable sheath  25  through which the said throttle cable  26  runs. The throttle blade  30  is connected to the connecting member  23  that links its motion to a belt  24 . When said throttle blade  30  moves the belt  24  is moved an identical amount. The belt is wrapped around a lower pulley  22  and an upper pulley  21 . On the side of the belt opposite where the said connecting member  23  is connected to the belt, a mass  20  proportional to that of the throttle blade  30  and a fraction of the return spring  28  is affixed to the belt. Said mass  20  is moved in a direction opposite that of the throttle blade  30  whenever the throttle blade is moved to open or close the air inlet restrictor. Said return spring  28  need only impart sufficient force on the throttle blade to overcome the friction in the device as the throttle blade  30  will show no tendency to move when the vehicle in which the inlet air restrictor is used is impacted. With this arrangement there should be no net mass movement other than that of the throttle cable when the air inlet restrictor is opened or closed. 
   Alternative embodiments of this air inlet restrictor could used other means to move the throttle blade  30  such as belting, chain, solid members, gear racks, hydraulic cylinders, or any alternative member acting in tension. 
   A mass could be moved in a direction opposing the movement of the throttle blade by using a system comprising of a gear train driving a gear rack. Another possible method would have some alternative tensioned member running around two or more points to which both a throttle blade and a mass are connected. 
   A lever arm could also be used to impart a motion on a mass that is opposite that of a throttle blade. A mass could be coupled to a throttle blade by a hydraulic system. 
   In an actual production version of this device, all components would likely be encased in a protective cover to prevent foreign material from interfering with the workings of the device. 
   A version of this device in which the moving mass and throttle blade are connected by only a flexible tensioned member will share some of the advantages of this design but the tendency of the throttle blade to bounce off its seat will not be restricted much. Rider fatigue will be reduced. 
   FIG.  4 .—Additional Component 
   A second possible embodiment of the engine air inlet restrictor shown in  FIG. 4 . is invaluable in situations where there is insufficient room on top of the cap  38  for an mechanism such as said connection member  23  to translate the motion of a throttle blade outside of the throttle body  37 . As with the engine air inlet restrictor depicted in  FIG. 3 . the, mechanism consist of a throttle body  36  in which a throttle blade  37  is moved by the intermediate throttle cable  39 . Since an unsupported cable can act only in tension and not in compression the return spring  35  must have sufficient preload to maintain tension in the throttle cable  39  at all times. 
   Traditional sliding throttle blade air inlet restrictors  37  fitted with sufficiently preloaded return springs  39  have a number of disadvantages. The heavy return spring  39  fatigues the operator diminishing both their control over the vehicle and it detracts from their riding experience. Though the heavy return spring  39  maintains constant tension in the throttle cable, it doesn&#39;t eliminate the variations in the force the operator must exert on the throttle lever when the vehicle is impacted and the throttle blade  37  wants to move independently of the vehicle. 
   One method of alleviating these issues is to connect the throttle blade  37  to a second mass  32  or masses whose motion is opposite that of the throttle blades. Note that in FIG.  4 ., the mass  32  is not connected to the intermediate throttle cable  39  and is instead connected to a second cable, the mass cable  43 . Since both the intermediate throttle cable  39  and the Cam Cable  44  are connected to the same roller  40 , they can have different masses provided the ratio of their mass to travel distance is relative to one another. For instance if the throttle blade  37  weights one pound and travels a total of one inch, then if the mass was running on a smaller diameter portion of the roller  40  than the throttle blade  37  and only moved one inch, then the mass would have to weigh two pounds to counterbalance the throttle blade. 
   Since tension must always be maintained in the mass cable  31  to maintain a proper weight balance between the throttle blade  37  and the mass  32 , a mass preload spring  31  is used to keep tension on the mass cable  43 . The mass preload spring  31  serves a second function in that it balances out the exorbitant amount of preload in the return spring  35 . However, with both springs functioning in the system, the throttle&#39;s rest position will be somewhat open. In an ideal world both the mass preload spring  31  and the return spring  35  would have sufficiently low spring rates such that a mass preload spring  31  could be specified with slightly less preload than is found in the return spring  35 . The mass preload spring  31  would have sufficient preload to tension the mass cable  43  and balance out most of the preload on the return spring  35 . As the throttle was opened, the amount of force exerted by both springs would change so minimally that the force exerted by the return spring  35  would not grow so great as to fatigue the operator, and the mass preload spring would maintain sufficient force to keep tension in the mass cable  43  and balance out the force exerted by the return spring  35 . 
   Since space constrains and design realities prevent us from obtaining springs with these ideally super low spring rates, the addition of a falling rate spring arrangement to the mechanism is necessary. A mass preload spring  31  is selected so that when the throttle blade  37  is open it can supply nearly as much force as the fully compressed return spring  35  is generating. The heavier mass preload spring  31  overpowers the return spring  35  holding the throttle wide open when the system is in equilibrium. To shift the equilibrium between the mass preload spring  31  and the return spring  35 , a second spring, the cam loader spring  34  works against the moving cam  33  which is connected to the roller  40  by the cam cable  44 . This arrangement bolsters the efforts of the return spring  35  to hold the throttle blade  37  closed when the system is at rest. As the throttle blade  37  is opened by turning the roller  40 , the tension on the cam cable, which is balancing out the efforts of the mass preload spring  31  and the return spring  37 , actually decreases. By tuning the profile of the cam  33  properly the engine air inlet restrictor in  FIG. 4 . can be configured so that in its rest position the throttle is closed. Minimal effort is necessary to open the throttle blade  37 , and the force necessary to open or close the doesn&#39;t change appreciably. 
   As with the air inlet restrictor described in FIG.  3 ., a cable, the main throttle cable  41  connects the air inlet restrictor to the thumb throttle actuator mounted on the vehicle&#39;s handlebars. The throttle cable sheath  42  preserves the distance of the path the main throttle cable  41  must take between the thumb throttle actuator and the air inlet restrictor. All elements of the device depicted are integrated into the cap  38  that is affixed to the throttle body  36 . 
   Alternative embodiments of this design concept could be mounted independently of the throttle body and connected to the throttle body only by a cable and some mechanism to preserve the distance the cable must travel between the two mechanisms. 
   A production version of this design would have all of the components enclosed in a closed shell to prevent foreign matter from interfering with the function of the device. The single mass preload spring  31  and the cam loader spring  34  might each be replaced by two or more springs doing the same function. To make all springs in the system function with much lower spring rates, several springs might be nested together. In this arrangement two or more coil springs would be arranged inside of one another so that the several short springs worked in unison to emulate the characteristics of a much longer spring as would be formed if all of the springs were connected end to end. 
   FIG.  5 .—Additional Component 
   An alternative design to what is depicted in  FIG. 1  is shown in  FIG. 5 . In the thumb throttle controller depicted in  FIG. 5 . a member, the contact slide  48  which slides parallel or close to parallel with the underside of the vehicle&#39;s handle bar. The contact slide  48  captures the motion of the operator&#39;s thumb using an electrical rheostat  45  that translates this information from the throttle with electrical wires  53 . The contact slide  48  slides through the body  46  that is secured to the handlebar  51  by two fasteners  52 . A return spring  47  returns the contact slide  48  to a rest position when not actuated by the operator. A sliding surface  50  built into the grip  49  facilitates the motion of the thumb along the underside of the handlebar when the operator opens or closes the contact slide  48 . 
   Many variations on this design are possible. A production version of this thumb throttle actuator would have the internals of this mechanism completely encased by a protective shield to prevent foreign matter from damaging its internals. A suitable seal would be used to prevent foreign liquids or matter from passing through any mating surfaces between the contact slide  48  and the body  46 . 
   Alternative variations of this sliding thumb throttle controller might add a member to the contact slide to close up the loop that the thumb is placed in so that the thumb isn&#39;t slid against the underside of the handlebar which would reduce the wear to the rider&#39;s gloves and make throttle control more precise. The handlebar could be custom shaped with a recess built into the underside of it to better accommodate the thumb throttle control. 
   A sliding thumb throttle controller as depicted in  FIG. 5 . can be linked to the throttle body with a traditional throttle cable, a hydraulic line, or an electrical or optical signal generated by a device other than the rheostat which can measure the displacement of the contact slide. 
   FIG.  6 .—Additional Component 
   An alternative design of what is depicted in  FIG. 3 . and  FIG. 4 . By using a stepper motor  62  to generate the motion which raises and lowers the throttle blade  56  running inside of the body  57 , this air inlet restrictor shown in  FIG. 6 . can be operated with only an electrical connection to the thumb throttle actuator and an electrical power source. 
   This design differs from a conventional air inlet restrictor in that attached to the cap  58  is a stepper motor  62  connected by a belt  61  to a reduction pulley  59 . The said reduction pulley  59  incorporates a portion of the position sensor  60  and has two running surfaces. The belt  61  connected to the stepper motor  62  is wrapped around the larger diameter running surface. The throttle cable is wrapped around a running surface with a smaller diameter. This arrangement provides some mechanical advantage for the stepper motor so a motor of reasonably low torque output has sufficient rotational torque to work against the return spring  55  which much have sufficient preload to prevent the throttle blade  56  from inadvertently bouncing from its rest closed position. 
   A functioning version of the device shown in  FIG. 6 . would have the stepper motor  62 , the belt  61 , the position sensor  60 , and the reduction pulley  59  enclosed in a protective cover to prevent foreign material from interfering with mechanism and to keep the internals lubricated if necessary. 
   The wrapped belt used to translate the rotation of the rotary motion generator which in  FIG. 6 . is a stepper motor  62  could be replaced by any other means of translating rotating motion from one shaft to another. Examples include using the same wrapped arrangement with another suitable flexible tension member such as a piece of wrapped fabric or wire. The shaft of the rotary motion generator and the rotating member that pulls the throttle cable  54  could also be linked by more conventional means such as a direct coupling, a gear drive, a chain drive, or a belt drive. Where necessary, to bolster or capitalize on the torque output of the rotary motion generator additional gear trains could be employed in the mechanism. 
   The stepper motor is powered and controlled by signals carried to it by the stepper motor wiring  63 . These electronic pulses are generated by a micro controller which using a combination of data from an electronic thumb throttle control and feedback signals generated by the position sensor  60  which are fed back to said micro controller along the position sensor wiring  64 . 
   Other rotary motion generators could be employed including but not limited to servo motors and hydraulic motors. Servo motors could be used with or without feedback circuits to determine throttle position. The use of a system that can measure throttle blade movement has the advantage of being configurable for use on motorcycles with different amounts of throttle blade travel. 
   Elements of the mechanisms described in  FIG. 3 . and  FIG. 4 . can be employed in the device shown in  FIG. 6 . to reduce the necessary torque output of whatever device is providing the necessary motion to move the throttle blade. 
   The throttle blade could be moved by a mechanism that doesn&#39;t rely on using a flexible member wrapped around a rotating shaft to pull a cable. An example would be to use a rotating screw thread to impart linear motion either directly or indirectly on the throttle blade. The throttle blade could be moved by a hydraulic, pneumatic, or vacuum actuator. 
   FIG.  7 .—Additional Component 
   Shown in  FIG. 7 . is a right side view of a typical motorcycle which would be fitted with a thumb throttle control and an air inlet restrictor as described in this patent. A motorcycle consists of a frame  73  that holds an engine  74  and is connected to a front steering system  66 . Connected to the front steering system  66  is the front wheel  65  and the handlebars  68 . Connected to the frame  73  either directly or by the means of a rear suspension system is the rear wheel  72 . Positioned in front of the rear wheel  72  are the footpegs  71  on which the rider place their feet. Located on top of the footpegs  71  is a seat  70  on which the rider sits. The rider reaches forward to place their hands on the handlebar or handlebars  68  on motorcycles with separate right and left handlebars. Mounted to the right handlebar  68  is the thumb throttle control  67  that the rider modulates to control the engine&#39;s power output. The thumb throttle control  67  is connected to one or more air inlet restrictors  69  that limit the air flowing to the engine so as to regulate the engine&#39;s power output. 
   FIG.  8 .—Additional Component 
   Shown in  FIG. 8 . is an overhead view of typical motorcycle which would be fitted with a thumb throttle control. Note the rear tire  72  that extends beyond the back of the motorcycle. Extending from the left and right sides of the motorcycle are the foot pegs  75  on which the riders rests their feet. On the motorcycle shown the seat  70  is mounted between the two foot pegs  75 . The seated rider leans forward their left and right hands on the appropriate handlebars  68  which are moved to steer the front tire  65 . Mounted to the right handlebar is the thumb throttle control  67  which the rider actuates with their right thumb in order to regulate the speed of the motorcycle. The location of the moving member in the thumb throttle control  67  below the handlebar  68  allows the rider to modulate the thumb throttle control  67  and the brake lever  76  simultaneously.