An operating device is provided for a human-powered vehicle. The operating device basically includes a base, a first operating member, a first electric switch, a first load generator and an operating load adjuster. The first operating member is movably arranged with respect to the base. The first electric switch is provided to the base and arranged to be activated by movement of the first operating member. The first load generator is configured to generate an operating load applied to the first operating member. The operating load adjuster is configured to adjust a transition of the operating load from a first load transition to a second load transition different from the first load transition.

Example bicycle suspension components are described herein. An example suspension component includes a spring and a damper configured in a telescoping arrangement. The shock absorber has a first end and a second end opposite the first end. The second end has an eyelet. The example suspension component also includes a shock end mount coupled to the first end of the shock absorber. The shock end mount includes a frame bracket. The frame bracket includes a first frame attachment portion to be coupled to a frame of the bicycle. The eyelet on the second end of the shock absorber defines a second frame attachment portion to be coupled to the frame of the bicycle. The shock end mount includes an elastomeric member to enable relative movement between the shock absorber and the first frame attachment portion. The elastomeric member is disposed outside of a region between the first frame attachment portion and the second frame attachment portion.

Example bicycle suspension components are described herein. An example suspension component includes a spring and a damper configured in a telescoping arrangement. The shock absorber has a first end and a second end opposite the first end. The second end has an eyelet. The example suspension component also includes a shock end mount coupled to the first end of the shock absorber. The shock end mount includes a frame bracket. The frame bracket includes a first frame attachment portion to be coupled to a frame of the bicycle. The eyelet on the second end of the shock absorber defines a second frame attachment portion to be coupled to the frame of the bicycle. The shock end mount includes an elastomeric member to enable relative movement between the shock absorber and the first frame attachment portion. The elastomeric member is disposed outside of a region between the first frame attachment portion and the second frame attachment portion.

Example bicycle suspension components and analysis devices are described herein. An example suspension component includes a first tube and a second tube configured in a telescopic arrangement having an interior space, a spring system including a pneumatic chamber containing a mass of a gas forming a pneumatic spring configured to resist compression of the telescopic arrangement, and a suspension component analysis (SCA) device. The SCA device may include a pressure sensor to detect a pressure of the gas in the pneumatic chamber and provide a signal indicative of the detected pressure and circuitry configured to receive the signal. The circuitry and the pressure sensor are at least partially disposed in the interior space.

Example bicycle suspension components and analysis devices are described herein. An example suspension component includes a first tube and a second tube configured in a telescopic arrangement having an interior space, a spring system including a pneumatic chamber containing a mass of a gas forming a pneumatic spring configured to resist compression of the telescopic arrangement, and a suspension component analysis (SCA) device. The SCA device may include a pressure sensor to detect a pressure of the gas in the pneumatic chamber and provide a signal indicative of the detected pressure and circuitry configured to receive the signal. The circuitry and the pressure sensor are at least partially disposed in the interior space.

A bicycle comprises a front wheel; a rear wheel; a frame comprising a main frame portion and an articulating frame portion, the articulating frame portion comprising: a lower arm pivotally supported at a first axis by the main frame portion; an upper frame link pivotally supported at a second axis by the main frame portion; an upper arm pivotally coupled to the upper frame link at a third axis; an upper shock link pivotally coupled to the upper frame link and the upper arm at the third axis; and a lower shock link pivotally coupled to the main frame portion and the lower arm at the first axis; and a shock absorber having a first end pivotally supported at a fourth axis by the main frame portion, and a second end pivotally supported at a fifth axis by the upper shock link and the lower shock link.

A bicycle includes a chainstay protector having an upper surface including a valley, a first peak, and a second peak. The first peak extends upwardly from the valley toward the chain and has a first contact surface positioned to contact the chain a first height above the valley. The second peak extends upwardly from the valley toward the chain and has a second contact surface positioned to contact the chain a second height above the valley. The first contact surface is spaced from the second contact surface by a gap that is at least 5 times the first height. Each of the first and second contact surfaces has a length that is less than the length of the gap and less than two times a pitch of the chain.

A bicycle includes a chainstay protector having an upper surface including a valley, a first peak, and a second peak. The first peak extends upwardly from the valley toward the chain and has a first contact surface positioned to contact the chain a first height above the valley. The second peak extends upwardly from the valley toward the chain and has a second contact surface positioned to contact the chain a second height above the valley. The first contact surface is spaced from the second contact surface by a gap that is at least 5 times the first height. Each of the first and second contact surfaces has a length that is less than the length of the gap and less than two times a pitch of the chain.

Disclosed herein are examples of motive power sources suitable to power a two-wheeled vehicle. The vehicle may include a suspension linkage and a suspended body. In some examples, the motive power source may include a housing with a boss extending therefrom. The boss may include a first securement structure. The securement structure may include an instantaneous velocity center of the suspension linkage when coupled to the two wheeled vehicle. In some examples, a second securement structure is formed in the suspended body, a bottom link forms a portion of the suspension linkage, the bottom link includes a third securement structure, and an axle is coupled to the first, second, and third apertures. In some examples, the first, second, and third apertures are concentric with the axle.

A human-powered vehicle control device is for a human-powered vehicle. The human-powered vehicle includes a motor that applies a propulsion force to the human-powered vehicle and a shifting device that changes a transmission ratio, which is a ratio of a rotational speed of a wheel of the human-powered vehicle to a rotational speed of a crank of the human-powered vehicle. The human-powered vehicle control device includes an electronic controller that is configured to control the shifting device to change the transmission ratio in accordance with a comparison of a first parameter related to the human-powered vehicle and a predetermined threshold value. In a case where an output of the motor decreases as a vehicle speed of the human-powered vehicle increases, the electronic controller is configured to change the predetermined threshold value.