Stimulation devices and methods of use are described herein. An example stimulation device configured to stimulate a portion of a body of a user comprises a housing that includes a casing and a covering. The casing includes a nozzle, a motor disposed within the casing configured to generate stimulation patterns, a drive shaft connected to the motor, a sensor configured to detect changes in the rotation of the draft shaft, a controller, and a battery. The covering covers a portion of the casing.

Systems and apparatuses related to the field of cardiac resuscitation, and in particular to devices for assisting rescuers in the administration of cardio-pulmonary resuscitation (CPR) are described herein. The system includes an adhesive pad configured to be adhered to at least a portion of a patient's chest, a sensor configured to be placed on the patient's chest and to measure at least one chest compression parameter during CPR treatment, and a landing pad having a coupling surface at least partially surrounding the sensor and configured for maintaining adherence with an active compression decompression device, the adherence sufficient to transfer decompression force between the active compression decompression device and the patient's chest during the CPR treatment.

An exercise device comprises a base. A power mechanism and a vibration mechanism are each disposed in the base. The power mechanism powers the vibration mechanism. The vibration mechanism provides linear vibrations through the base of the device in a first axis parallel to a longitudinal axis of a user standing on the base. In some embodiments, the device is substantially free of vibration in a plane orthogonal to the first axis and is substantially free of rotational vibration in any direction at a time when the vibration mechanism provides the first plurality of linear vibrations. In some embodiments, the vibration mechanism operates between 10 and 60 Hz. In some embodiments an exercise kit is provided that includes the referenced exercise device, an exercise bar, and one or more elastic bands, each elastic band for removably coupling the base to the exercise bar.

A health hazards geolocation control system for monitoring potential health hazards (PHHs) endangering users using the system for detecting PHHs endangering them, for example a pedestrian, wherein the system may include a personal health hazards monitoring system having an image capturing and processing units, and wherein the image sensor is situated in the vicinity of the user, for example, by wearing it or is flown by a drone associated with that system. Upon detecting a PHH the system warns the user to prevent their fall. The geolocation control system, or similar systems of, may be by the user or other users, to form a pool of health hazards and associated score. Thus, other users on that location may be warned of the reported health hazard. The system may advise a user which is the safest path to walk, having a minimal, level or number of PHHs, and highest safety score.

The present invention relates to a method for controlling an acupressure force and a body scan in real-time and, more specifically, the method comprises the steps of: (a) setting a reference vertical height for each horizontal position of an acupressure part, and setting a target acupressure force within the range of the reference vertical height; (b) calculating a current measurement acupressure force by means of a user's load measurement data applied to a load cell; and (c) comparing the target acupressure force with the current measurement acupressure force so as to control the vertical height of the acupressure part. That is, the present invention presents a method for controlling a body scan in real-time, the method enabling: an inflection point of a driving current measurement value applied to a horizontal driving motor to be measured during the horizontal driving of an acupressure part in an initial massage process, so as to reflect, on an acupressure force correction value, a deviation between a vertical position of the acupressure part corresponding to the inflection point and a reference vertical position, for each horizontal position, stored in a database, thereby calculating a new target acupressure force; and the new target acupressure force to be reflected in acupressure control such that an acupressure force suitable for a user can be provided during a massage.

An exercise device comprises a base. A power mechanism and a vibration mechanism are each disposed in the base. The power mechanism powers the vibration mechanism. The vibration mechanism provides linear vibrations through the base of the device in a first axis parallel to a longitudinal axis of a user standing on the base. In some embodiments, the device is substantially free of vibration in a plane orthogonal to the first axis and is substantially free of rotational vibration in any direction at a time when the vibration mechanism provides the first plurality of linear vibrations. In some embodiments, the vibration mechanism operates between 10 and 60 Hz. In some embodiments an exercise kit is provided that includes the referenced exercise device, an exercise bar, and one or more elastic bands, each elastic band for removably coupling the base to the exercise bar.

A method for controlling target massage equipment, a device for controlling the target massage equipment, and a non-transitory computer readable storage medium. The method includes obtaining at least one of an arm swing frequency or a total exercise intensity when a user is doing exercise through a wearable device, obtaining exercise information according to the at least one of the arm swing frequency or the total exercise intensity, and controlling the target massage equipment to operate according to the exercise information.

An operator supervising a wearer of an exoskeleton is verified by performing a verification routine on the operator using the exoskeleton. If the verification routine is unsuccessful, the exoskeleton is caused to follow a pre-established response routine. If the verification routine is successful, movement of the exoskeleton is allowed.

A system for electrical ventilation stimulation of a patient including an implantable nerve stimulator including a stimulation circuit and a pulse generator that produces biphasic charge-balanced pulses to stimulate a phrenic nerve, an external digital programming device having near field communication transmission and a digital interface, and wherein the external digital programming device is used to control settings of the implantable nerve stimulator.

A portable battery power operated chiropractic adjusting instrument, manipulator or thruster for applying a selectable adjustment energy impulse to a patient through a plunger having a resilient or cushioned head with the energy impulse applied to the plunger being supplied by a solenoid. The adjusting instrument can have annunciators or indicators for preload, readiness to operate, level of energy impulse and the like. The power source can be an internal rechargeable battery or removable rechargeable battery pack.