A degree-of-health outputting device is provided with a display unit, an operating unit, and an output unit. The display unit displays a captured image of a region, the state of which changes according to a degree of health in a living body, and displays a plurality of comparison images having different degrees of health obtained on the basis of a reference image of the region captured prior to the time the abovementioned captured image was acquired for the same living body. The operating unit is provided in order to select one of the plurality of comparison images displayed by the display unit. The output unit (e.g., the display unit) outputs (e.g., displays) information relating to the degree of health of the living body on the basis of the comparison image selected through use of the operating unit.

A reading device, applied with at least one temperature sensing device and at least one external device; the temperature sensing device electrically connected with the reading device, comprising at least one temperature sensing patch which is capable of attaching on human skin, and sensing as well as recording body temperature change; the outer device being connected with, the reading device by a wireless communication; the reading device comprising: a housing, a data transmission port group, a screen, an external device connection port group, a memory unit, a processor unit, a control interface, and a wireless communication unit; the reading device is capable of reading and integrating the body temperature data obtained from the temperature sensing patch, and transmitting rapidly to the external device, whereby the medical personnel could quickly and easily know a patient's body temperature change, and effectively determine the patient's condition

Disclosed is a human body frequency diagnostic analysis apparatus including a transceiver with an end connected to a human head and driven to transmit a transmission frequency and drive the human head to feed back a feedback frequency, a detection unit connected to the transceiver for driving the transceiver to transmit the transmission frequency and receive the feedback frequency, and a control unit connected to the detection unit for controlling the detection unit and includes a computing unit for computing and comparing the transmission frequency with the feedback frequency to generate a dual line spectrum, a database for comparing the dual line spectrum to generate detected information, and a screen for displaying the dual line spectrum and the detected information. A maximum drop value detected in a frequency section of the dual line spectrum indicates an imbalance of a human body frequency.

An electronic device comprises a sensor, a notifier and a controller. The sensor is urged to a test part side of an examinee and can detect pulsation at the test part. The notifier notifies information for a position of the sensor at the test part. The controller controls the notifier to notify information for a position of the sensor at the test part based on pulsation at the test part detected by the sensor.

A system and method for producing sound signals that comprises an image capturing device to capture an auric color representation of a body part of a person. The auric color representation represents a blocked energy area of the body part. A processing device divides the auric color representation into a plurality of arcs. A display device communicating with the processing device displays the plurality of arcs. A transcranial sound stimulation device determines a block-breaking frequency corresponding to the blocked energy area. A tone generator generates a set of wave-patterns corresponding to the block-breaking frequency. An audio device produces sound signals based on the set of wave-patterns, to be heard by the person thereby healing the blocked energy area of the body part.

A meridian impedance measurement device and method are provided, including: at least one set of measurement electrodes placed on the wrists or ankles, each set including six measurement electrodes in contact with six corresponding meridians; at least one reference electrode placed on the wrists or ankles, simultaneously being in contact with all the six corresponding meridians; at least one impedance measurement unit; a microprocessor; an impedance display unit; and a storage unit. During measurement, the adjustable voltage output unit delivers voltage to each pair of measurement electrode and reference electrode, the impedance measurement unit collects signals and pass the signals to the microprocessor for calculation. The whole procedure is done automatically and can be built into a wearable device.

A wristband pulse diagnosis instrument including two pulse diagnosis instrument units is provided. Each of the two pulse diagnosis instrument units includes a wristband body, a pressure sensor, a first adjusting mechanism, and a second adjusting mechanism. A connecting member is disposed at each of two sides of the wristband body, and the connecting members are used to selectively connect the two pulse diagnosis instrument units to each other. The pressure sensor is movably disposed on the wristband body via the first adjusting mechanism and the second adjusting mechanism. A depthwise movement of the pressure sensor is adjusted by the first adjusting mechanism for the pressure sensor to move to three pulse positions of floating, medium, and deep, and a lateral movement of the pressure sensor is adjusted by the second adjusting mechanism for the pressure sensor to move to three pulse positions of distal, mid, and proximal.

The objective of the present invention is to provide a hardness meter which estimates hardness in a stable manner regardless of a compression strength. Disclosed is a hardness meter characterized in being provided with: a movable portion which is continuously pressed against an object to be measured; a sensor which outputs an output signal reflecting a reaction force at a part of the object to be measured that is in contact with the movable portion; a motive force mechanism that causes the movable portion to perform a piston motion; and a hardness estimating portion which estimates the hardness of the object to be measured on the basis of an alternating current component of the output signal, generated by the piston motion of the movable portion.

A method for detecting a particular syndrome based on hemodynamic analysis that includes steps of: obtaining a piece of hemodynamic data representing a hemodynamic waveform; performing moving average (MA) filtering on the hemodynamic waveform to obtain a filtered waveform; determining troughs in order to determine waveform segments of the filtered waveform; determining systolic peaks for determining first and second portions of the waveform segments; determining smoothness of the second portions; and determining a relation between the hemodynamic waveform and a particular syndrome based on the smoothness of the second portions, and generating a detection result.

A probe device provides an enhanced bioelectric and spring-loaded sensing tip with an integrated force sensor. The probe device measures the bioelectric conductance value from a patient for therapeutic and/or diagnostic purpose using the spring-loaded sensing tip. In addition, the probe device measures the force applied by the spring-loaded sensing tip against the patient using the integrated force sensor. Using feedback from the force sensor and the bioconductive data of the patient, the force applied at the spring-loaded sensing tip may be adjusted to obtain improved results.