The present invention relates to systems, methods, and apparatus that facilitate exercise in vehicles. In particular, the present invention provides active exercise in passenger and navigation areas in vehicles by incorporating force sensors in the environment surrounding the passenger and/or navigator in the vehicle. The present invention applies the principles of isometric training and interacts with a remote or on-board computer platform to track, measure and provide instruction to the passage and/or navigator engaged in such isometric training.

The present application provides a fitness resistance band. The fitness resistance band includes a handle assembly and a resistance band body, where the handle assembly includes a handle body and sleeve rings, first connecting parts are further disposed on the sleeve rings, and the resistance band body is connected to the first connecting parts. The handle assembly is provided with the handle body and the sleeve rings, the sleeve rings can rotate relative to the handle body. In use, the resistance band body can rotate together with the sleeve rings, so that relative rotation occurs between the sleeve rings and the handle body, friction between the resistance band body and the handle body is avoided, and the resistance band body is protected from wear.

A treadmill includes a frame, an exercise deck attached to the frame, and a first handle movably attached to the frame. The first handle has a first orientation where the first handle is positioned within a region above the exercise deck and stabilized to support a user's weight during a body weight exercise, and a second orientation where the first handle is positioned away from the region above the exercise deck.

Presented is an exercising apparatus capable of capable of being used by a user for performing a variety of physical exercises. The exercising apparatus includes a handle, a mounting assembly, a clamp assembly and an arm extension assembly. The arm extension assembly includes multiple telescopically nestable arms. At least one telescopically nestable arm includes a weight attachment portion such that a user can lift weight attached to the weight attachment portion of the arm extension assembly by moving the handle. The mounting assembly is configured to allow rotation of the arm extension assembly in at least one direction. The exercising apparatus is collapsible and could be easily assembled and disassembled and installed at multiple locations depending on the user's requirements.

An exercise anchor for elastic bands or other exercise implements that mounts to a standard door hinge. The exercise anchor allows for an easy, secure, and unobtrusive mounting to a door hinge through the hinge pin, or with a hinge pin integrated into the exercise anchor. It may also be provided as a kit with a variety of specialized hinge pins to provide extra support or to adapt a single exercise anchor to hinges that require hinge pins of differing shaft diameters or differing lengths. The exercise anchor may be mounted without the need to modify or drill into walls or fixtures, and may include features for added security and to prevent inadvertent pull-out of the anchor, such as anchor braces, bump stops, and hinge captures. The exercise anchor may also include a variety of band capture shapes, geometries, or arrangements allowing use versatility when engaging in various exercises.

Interactive/smart resistance band training systems include one or more resistance bands connected to a force sensing unit that registers the force exerted by a user on handles connected to the bands. The sensing unit operates effectively regardless of whether the user is training with one handle individually, or with two handles being pulled in parallel or non-parallel directions. The systems may correct the force readings to account for non-alignment between the force-measurement axis of the force sensing unit and the directions in which the user applies force to the resistance bands. The systems may guide a user through exercise sessions tailored to the fitness level of the user; may display the force readings, calories burned, and other performance parameters and goals on a continuous, real-time basis; may summarize the result of the exercise session; and may recommend subsequent exercise sessions based on the performance of the user.

A rigging system is configured for selective attachment to a fixed-point mount (e.g., a beam, a bar, or a door jamb), typically located at a position above the user's head. A handle on the opposite end of the rigging system hangs from this fixed point and is grasped by the user to support a portion of the user's weight while the user performs resistance exercises against a reduced portion of the user's body weight. In some configurations, the fixed point may be a doorjamb above the top of a door. A height adjustment buckle of the rigging system is designed to be positioned generally distal from a structure forming the handle during use of the rigging system.

The present disclosure relates to a modular strap-based exercise apparatus, kit, and method of use thereof, and more particularly to an apparatus, kit, and method for modularly connecting components of a strap-based exercise device. In an embodiment, the strap-based exercise apparatus includes one or more infinity loops configured to attach various portions of the exercise apparatus together. The exercise apparatus may be provided as a kit including an elongated member, a grip assembly, and one or more mechanisms for adjusting the length of a strap and connecting straps together.

A fitness device contains a strap, a handle, and a plate. The strap is substantially inelastic and flexible. The plate is substantially rigid. The handle at least partially envelopes the strap. A method of exercising with such a fitness device is also described herein. Other fitness devices and other methods of use are also described herein.

A handheld resistance exercise device is contemplated for exercise, rehabilitation, warm-up and the like, which provides resistance to muscles, tendons, joints, and fasciae in the upper body and lower back as it is actuated by a user standing a distance away from a vertical surface that is engaged with the device. Actuation thereof by the user in performing various exercise protocols provides stability for one or more muscles of the hand, elbow, shoulder girdle, shoulder blade, rib cage, as well as the inner core muscles, while also providing improved mobility for one or more of the wrist, forearm, elbow, shoulder joint, and muscles that rotate and bend the spine sideways.