초록 ▼

This system includes a self-contained, non-invasive system for collecting work and power performance data on nearly any kind of repetitive-motion exercise. See the glossary for definitions of terms used in this specification. It is non-invasive in that no permanent modifications need made to existin

This system includes a self-contained, non-invasive system for collecting work and power performance data on nearly any kind of repetitive-motion exercise. See the glossary for definitions of terms used in this specification. It is non-invasive in that no permanent modifications need made to existing exercise equipment. It is a battery-powered system that remotely senses iterations of a moving part or body member, and records them with a time-stamp. It also records weight and distance of travel if they are input--but for some exercises this function may be deemed not necessary, or ignored. If time, weight, and distance are known then work and power metrics can be calculated on the data when it is analyzed on a host computer. This data can then be graphed to provide comparisons from workout session to workout session. The user can detect trends, and differences in performance as workout variables are manipulated. Workout variables include, but are not limited to: weight, distance of travel, time, order of exercise stations, number of sets, number of repetitions per set, pattern of weight increase/decrease for a given exercise station over the sets, pattern of extension and contraction per repetition, etc.

대표청구항 ▼

This system includes a self-contained, non-invasive system for collecting work and power performance data on nearly any kind of repetitive-motion exercise. See the glossary for definitions of terms used in this specification. It is non-invasive in that no permanent modifications need made to existin

This system includes a self-contained, non-invasive system for collecting work and power performance data on nearly any kind of repetitive-motion exercise. See the glossary for definitions of terms used in this specification. It is non-invasive in that no permanent modifications need made to existing exercise equipment. It is a battery-powered system that remotely senses iterations of a moving part or body member, and records them with a time-stamp. It also records weight and distance of travel if they are input--but for some exercises this function may be deemed not necessary, or ignored. If time, weight, and distance are known then work and power metrics can be calculated on the data when it is analyzed on a host computer. This data can then be graphed to provide comparisons from workout session to workout session. The user can detect trends, and differences in performance as workout variables are manipulated. Workout variables include, but are not limited to: weight, distance of travel, time, order of exercise stations, number of sets, number of repetitions per set, pattern of weight increase/decrease for a given exercise station over the sets, pattern of extension and contraction per repetition, etc. the inner wall surface (16) of the cavity (12). 2. The watertight connector of claim 1, wherein the channel (20) is formed along a widthwise lateral edge of the inner wall surface (16) of the cavity (12) having a back-to-back relationship with the sealing surface (14). 3. The watertight connector of claim 2, wherein mold-removal slits (21) are formed at the opposite sides of the locking portion (23) by removing a mold when the connector housing (10) is molded by the mold. 4. The watertight connector of claim 3, wherein the channel (20) and the mold-removal slits (21) communicate with each other. 5. The watertight connector of claim 4, wherein the channel (20) is wider than the mold-removal slits (21). 6. The watertight connector of claim 1, wherein a mating connector (M) can be pulled into the housing (10) and connected therewith by a cam action of a cam mechanism (Mp, 25) when a lever (24) on the watertight connector is rotated. 7. A watertight connector (F) having a housing (10) formed from a synthetic resin, the housing (10) having opposite front and rear ends, at least one outer wall (19) extending between the front and rear ends, said outer wall (19) defining an outer peripheral surface of the housing (10), a portion of the outer peripheral surface between the front and rear ends defining a sealing surface (14), at least one cavity (12) extending through the housing (10) from the rear end to the front end thereof, the cavity (12) being formed partly by the outer wall (19), a resiliently deflectable lock (17) being formed in the cavity (12) and being cantilevered forwardly from a location on the outer wall (19) forwardly of the sealing surface (14), at least one channel (20) being formed in a surface of said outer wall (19) facing into the cavity (12) and extending from the lock (17) rearwardly to a location rearward of the sealing surface (14), such that said channel (20) is in substantially back-to-back relationship with said sealing surface (14). 8. The watertight connector of claim 7, wherein the cavity (12) has opposed sidewalls extending substantially orthogonally from the outer wall (19) and spaced from said lock (17) by a: selected distance, said channel (20) being wider than the distance between the sidewalls of the cavity (12) and the lock (17). 9. The watertight connector of claim 8, wherein said cavity (12) has two of said channels (20) disposed respectively adjacent the sidewalls of the cavity (12). 10. The watertight connector of claim 9, wherein the mold-removal slits (21) communicate with the channels (20). 11. The watertight connector of claim 10, wherein the cavity (12) includes a ceiling (16a) rearwardly of and substantially aligned with the lock (17), the channels (20) being on opposite respective sides of the ceiling (16a). 12. The watertight connector of claim 10, wherein each of the channels (20) has a depth measured perpendicular to the outer wall (19) that exceeds the width of the channel (20) measured parallel to the outer wall (19). tion and the conductive portion of the connector housing, wherein the arm portion extends so as to be deformable in both of a parallel direction and a perpendicular direction with respect to a direction in which the cylindrical portion extends, and the arm portion includes a substantially plated-shaped member with a bent portion therein, the bent portion has one of a U-shape and a V-shape. 2. The connecting structure as set forth in claim 1, further comprising a collar member fitted around the cylindrical portion, wherein the shield member of the shielded cable is folded back and cramped between the outer periphery of the cylindrical portion and the collar member. 3. The connecting structure as set forth in claim 1, the arm portion is spaced away from the face of the connector casing on which one end portion of the arm portion is fixed. 4. The connecting structure as set forth in claim 1, further comprising a bus bar disposed in the connector housing and connected to the core wire of the shielded cable. 5. The connecting structure set forth in claim 1, wherein the surplusage bent portion provides deformability of the arm portion in at least a direction perpendicular with respect to a direction in which the cylindrical portion extends. 6. The connecting structure set forth in claim 1, wherein a surplusage bent portion is formed on the arm portion. 7. The connecting structure set forth in claim 6, wherein the surplusage bent portion provides deformability of the arm portion in at least a direction perpendicular with respect to a direction in which the cylindrical portion extends.