TWM454180U - Skin impedance measurement device having high, middle, and low frequency measurement signal output - Google Patents

Abstract

This creation relates to a high, middle, and low frequency wave output device, and to a skin impedance measurement device having a high, middle, and low frequency wave output, and to a skin impedance measurement device.

Description

Energy output device with high, medium and low frequency and combined with a skin-to-electrical spectrum Impedance measuring device

The present invention relates to an energy output device having a high, medium, and low frequency, and a device for measuring the impedance of a skin to electrical spectrum, especially a high, medium, and low frequency output frequency, waveform, power, and pause time, and the frequency and waveform of the carrier thereof are safe. Within the specified value, the output can be arbitrarily set to be added to the human body, and the feedback of the feedback signal can be used to measure the treatment and measurement devices of human skin (meridian, acupoint) for various frequency and waveform impedance changes.

The high, medium and low frequency therapy device can treat the pain of the body. The Chinese and Western medicine industry has been working for a long time. It is decided that the instrument is based on the waveform, frequency, pause time and power as the main output physical quantity. The traditional part of the instrument of the traditional high, medium and low frequency therapy device There are the following disadvantages: (a) the traditional general low-frequency therapy device can only adjust the power; (b) the traditional frequency is generally only available to the user, only a few frequencies can be selected, can not be arbitrarily set by the program; (c) for the traditional output Generally, only a few waveforms of a fixed waveform shape can be set, and the shape of the output waveform can not be arbitrarily set by a user of a conventional high, medium, and low frequency therapy device; (d) the conventional output power is generally a continuous waveform output, wave and wave. Any setting between which the pause time cannot be programmed; (e) The waveform of the conventional output has no carrier setting, let alone the carrier frequency and the waveform can be programmed.

Skin current impedance measurement is currently recognized as a good way to know the health of the body through the measurement of the direct current impedance of the skin. Japanese good guide system, West Germany Dr.VoLL system. However, if the traditional high, medium and low frequency therapy device does not combine the skin impedance feedback detection part, it has the following disadvantages: (1) The traditional high, medium and low frequency therapy device does not have a feedback signal, so the traditional high school low frequency therapy device cannot. Provide the user as a reference for the optimal setting of output frequency, waveform, power, and pause time; (2) The traditional existing measurement of skin impedance change products only stays on the human body DC measurement, and the DC current changes back to the skin impedance. The measurement of the signal can not be used to measure the frequency, waveform and power applied to the non-DC of the human body; (3) The traditional skin impedance measurement only measures the skin impedance under DC, and there is no non-high-frequency low-frequency filling. The DC signal measures down the skin impedance.

The present invention provides an energy output device having a high, medium, and low frequency, and a measuring device combining a skin to electrical spectral impedance, comprising: an input device for generating a predetermined main wave and carrier having a high, medium or low frequency Input digital data under the indication of frequency, waveform, power and pause time; a programmable logic gate for programming hardware logic to control the logical combination of the device; a microprocessor connected to the input device and the The program logic gate is combined with the microprocessor through an application program for processing and processing the input digital data and outputting corresponding programmable frequency and waveform energy, and processing the skin (via a signal that responds to the impedance of the energy-energy spectrum and outputs the signal; a programmable frequency and waveform and its carrier and frequency waveform generator are coupled to the microprocessor, having a digital analog converter and a a first low pass filter, the digital analog converter is configured to convert the digital data into an analog frequency and a waveform signal, and the first low pass filter is configured to filter the resonant noise, and generate a data according to the input digital data. Stylized waveform, frequency, and frequency and waveform of any carrier wave; a programmable power amplifier coupled to the programmable waveform generator for amplifying the power of the first waveform signal to generate a a second waveform signal of the most appropriate energy level; a programmable output outputter coupled to the programmable power amplifier, wherein a control signal can be used to programmatically assign and input the second waveform signal to output an energy A first contact member is selected to output an energy signal to a portion of a user's body.

According to the present invention, a high-medium-low-frequency energy output device and a measuring device for combining a skin-to-electrical spectral impedance, in combination with a skin-to-electrical spectral impedance measuring device, includes: a programmable input device via The programmable input device selects a second contact member for use in series with the user's body, and connects another portion of the body via the second contact member to form an electron at the programmable output output device. The loop outputs a first feedback signal: a feedback signal amplifier connected to the first feedback signal of the programmable input device for amplifying the first feedback signal and outputting a second feedback signal; a second low pass filter connected to the feedback signal amplifier for filtering the noise of the second feedback signal to generate a third feedback signal; and an analog digital converter connected to the second low a pass filter for converting the third feedback signal from the analog signal into a digital output signal and input to the microprocessor for processing the data by using the microprocessor; and an output device for displaying the micro An output signal processed by the processor that represents a measure of the change in impedance of the electrical spectrum of the body after the user's body has added the body to high, medium, or low cycle energy.

According to the present invention, the energy output device having high, medium, and low frequency and the measuring device combining the impedance of the skin to the electrical spectrum further include an overcurrent detector, when the current of the first feedback signal exceeds a predetermined value or a maximum safety value. Then, an overcurrent detection signal is output to the overcurrent safety switch of the programmable output output device to be turned off, and the overcurrent detection display is sent through the microprocessor.

According to the present invention, preferably, the frequency of the high, medium and low cycle energy is between 0.01 Hz and 100 MHz.

According to the present creation, preferably a portion of the body of the user is energized A human acupuncture point.

According to the present invention, the energy output device having high, medium, and low frequency and the measuring device combined with a skin-to-electrical spectral impedance further include a memory connected to the microprocessor for memorizing the data processed by the microprocessor and The device's own program data.

According to the present invention, preferably the memory is a flash memory (FROM) or a static memory (SRAM).

According to the present invention, preferably the input device is a key combination.

According to the present invention, preferably the output device is an LED digital display.

According to the present invention, preferably the first contact member is a conductive patch, a copper pedal, a copper hand grip, a hand grip probe or a drug tray.

According to the present invention, preferably the second contact member is a conductive patch, a copper pedal, a copper hand grip or a hand grip bar.

According to the present invention, preferably, the first waveform signal is a sine wave, a square wave, a triangular wave, an arbitrary waveform or an arbitrary waveform having a carrier wave.

The present invention provides a high-medium-low-cycle energy output device and a skin-to-electrical spectral impedance measuring device comprising: a programmable input device for selecting a second contact member for use by a programmable input device Connected to the user's body, and connected to another part of the body via the second contact member, forming an electronic circuit in a programmable output output device and outputting a first feedback signal: a feedback signal amplifier, Connecting to the first feedback signal of the programmable input device for amplifying the first feedback signal and outputting a second feedback signal; and a second low pass filter connected to the feedback signal amplifier for use Filtering the noise of the second feedback signal to generate a third feedback signal; and an analog-to-digital converter connected to the second low-pass filter for using the analog signal by the third feedback signal Converting into a digital output signal and inputting to a microprocessor for processing data by using the microprocessor; and an output device for displaying an output signal of the result processed by the microprocessor , After which represents the user's body for high, medium or low frequency energy filling the body, the body of a change in the electrical impedance spectrum of a measure of value.

According to the present invention, the energy output device having high, medium, and low cycles and a measuring device incorporating a skin-to-electrical spectral impedance are used under safe values for treating tumors or pain.

Please refer to FIG. 1 . FIG. 1 is a schematic diagram of a high-medium-low-frequency energy output device combined with a skin-to-electrical spectral impedance measuring device. The energy output device with high, medium and low frequency is combined with a skin pair. The electrical spectral impedance measuring device 100 has a body 101. The body 101 is electrically connected to the outside to select a conductive patch A1, A2, A3, A4, a copper hand grip B1, B2, a copper foot pedal C1, C2, a drug tray D1, and a hand detecting probe E1. Or hold the test stick F1 in one hand. When the user (such as a patient) uses the spectral impedance measuring device, as in the second figure, the contact interface (such as the first contact member or the second contact member) is respectively contacted to the part of the user's body, for example, measuring the hand In the acupoint spectrum, the hand holding the detecting rod F1 is held in one hand, and the other hand is holding the detecting probe E1 in contact, thereby forming a circuit loop, and the energy output device having high, medium and low frequency is combined with a skin-to-electrical spectral impedance. The display on the measuring device 100 displays a measure of the impedance of the human skin to the electrical spectrum, the measured value being a percentage value relative to the no-load full scale after feedback amplification.

Please refer to FIG. 2, which is a circuit diagram of a high-medium-low-frequency energy output device and a measuring device for combining skin-to-electrical spectral impedance. The energy output device with high, medium and low frequency is combined with a skin pair. The electrical spectral impedance measuring device includes a microprocessor 201. A button 2011 is electrically connected to the microprocessor 201 for generating an input setting of the indication of the high, medium and low frequency waveform data, and the indicated input waveform may be a sine wave, a square wave, a triangular wave, a trapezoidal wave, or other various shapes. Waveforms, other various irregular shape waveforms, when When the input waveform is an irregular waveform, the waveform shape data of the irregular waveform may be input, and the carrier frequency and waveform of the waveform may also be input through the input device. An LED digital display 2012 is electrically coupled to the microprocessor 201 for displaying the feedback signal spectral energy related values. A programmable logic gate 2013 is electrically coupled to the microprocessor 201 as a control circuit for all logic combinations of the present device circuitry. A memory 2014 is electrically connected to the microprocessor 201 for storing data and program data processed by the microprocessor.

The energy output device having high, medium, and low frequency and the measuring device combining the skin-to-electrical spectral impedance includes a programmable frequency waveform and carrier frequency waveform generator 202 for generating frequency and waveform shape data according to the output of the microprocessor. a first frequency and waveform signal 2023, comprising a digital analog converter 2021 and a first low pass filter 2022, the digital analog converter 2021 is configured to convert the frequency and waveform shape data into analog signals, and then The analog signal passes through a first low pass filter 2022 to filter out the resonant noise and output a high, medium, and low frequency first waveform signal 2023. The high, medium and low frequency frequencies are between 0.001 Hz and 100 MHz and can be programmed arbitrarily.

The first waveform signal 2023 is input to a programmable power amplifier 203, and the power of the first waveform signal 2023 can be arbitrarily set and amplified in a safe range to generate a second waveform signal 2031. The programmable power amplifier 203 is Electrically coupled to the programmable frequency waveform generator 202.

After the second waveform signal 2031, a programmable output outputter 204 is input, and a programmable signal is output through the 2013 programmable logic gate to select a programmable output. The second waveform signal 2031 is input to output energy (therapeutic energy and measurement signal) 2041 (for example) a conductive patch A1, and the user presses the conductive patch A1 on the hand position of the user 3 (such as a hole). Then, the other hand of the user 3 holds the copper hand grip B1, and thus (the loop signal 31 flows through the body of the user 3), the energy outputted by the device is injected into the body of the user 3 in series.

After that, the loop signal 31 is input to a programmable input device 205, and a first feedback signal 2051 is outputted therefrom.

Then, the first feedback signal 2051 is input to a feedback signal amplifier 206, and the first feedback signal 2051 is amplified to output a second feedback signal 2061, and the second feedback signal 2061 is input to an overcurrent. The detector 208, when the current of the second feedback signal 2061 exceeds a predetermined value or a maximum safety value, sends an overcurrent detection signal 2081 to control an overcurrent safety switch 2042 through A to cut off the programmable allocation. The switch in the output device 204 prevents excessive current from flowing through the user 3 to ensure user safety, because the current that humans can tolerate has a safe maximum value; if the current of the second feedback signal 2061 does not exceed At a predetermined value, the switches in the programmable output distributor 204 are not turned off and the treatment measurement continues. At the same time, the overcurrent detection signal 2081 is input to the microprocessor 201 to inform the microprocessor 201 of the overcurrent state of the overcurrent detection signal 2081. At the same time, an overcurrent state is displayed on the display 2012.

The second feedback signal 2061 filters the noise through a second low-pass filter 207 to generate a third feedback signal 2071, which is input to an analog-to-digital converter 209, and outputs a digital output signal 2091, and then inputs to Microprocessor 201, The digital signal from the fourth feedback signal 2091 is calculated by the microprocessor 201, divided by the percentage of the unloaded fourth feedback signal value, and then output to the LED digital display 2012 to display the energy-implanted skin-to-electron spectrum. The measure of the impedance (relative attenuation value).

Please refer to FIG. 3, which is a schematic diagram of the energy wave (therapeutic wave and measurement signal) 2041 of the present creation, and the pause time t2 between two adjacent waveforms, and the time occupied by the waveform is t1, wherein The horizontal axis is time and the vertical axis is amplitude (voltage value).

Please refer to FIG. 4, which is another schematic diagram of the energy wave (therapeutic wave and measurement signal) 2041 of the present invention having a carrier wave. The carrier frequency and the waveform can be arbitrarily set in a waveform of two adjacent carriers. The pause time t4 is between, and the time occupied by the waveform is t3, where the horizontal axis is time and the vertical axis is amplitude (voltage value).

The advantages of this creation are as follows:

(1) The energy output device with high, medium and low frequency, and the device for measuring the impedance of the skin to the electrical spectrum of the present invention--the frequency, output waveform, power and pause time of the high-medium-low-cycle output of the present device, and The frequency and waveform of the carrier can be arbitrarily set and output within the safety specified value. The traditional general high, medium and low frequency therapy device does not have the function of carrier modulation.

(2) The skin-to-electrical spectrum impedance feedback detection part of the present invention--the frequency of the high-medium-low-frequency energy output device and the high-medium-low-frequency wave outputted by the measuring device combined with a skin-to-electrical spectral impedance, Waveform, power, pause The change between the waveform of the carrier frequency and the carrier frequency is added to the human body. The energy output device with high, medium and low frequency, and the circuit of the measuring device for combining the impedance of the skin with the skin, the feedback signal, digital The storage, processing, processing, and output to the display, the user can use the high-middle and low-cycle output frequency, waveform, power, and pause time as the reference of the optimal output setting value, so that the energy output device with high, medium, and low frequency is combined with one The skin's measure of electrical spectral impedance achieves the best therapeutic effect,

(3) Safety: The energy output device with high, medium and low frequency, and the safety of the device combined with a skin-to-electrical spectral impedance. The current law I knows the current I=voltage V/impedance Z. Although the high-medium-low frequency is very low in the human body, the current flowing through the human body is very low, but when the human body resonates with a certain frequency waveform, the human skin impedance Z will become Very low, causing a great current to be added to the human body and causing damage. According to the setting of the overcurrent safety switch 2042 in Fig. 2, the first feedback signal 2051 of the human body is amplified and then input to the comparator for comparison with the set maximum safe current or the maximum safe current of the human body. If the current value is too large, The output relay is automatically turned off to prevent excessive current damage, so this creation has greater security.

100‧‧‧ energy output device with high, medium and low frequency and combined with a skin-to-electrical spectrum impedance measuring device

101‧‧‧ Ontology

A1, A2, A3, A4‧‧‧ conductive patch

B1, B2‧‧‧ copper hand grip

C1, C2‧‧‧ copper pedals

D1‧‧‧ drug tray

E1‧‧‧Hand grip detection probe

F1‧‧‧Hand grip test stick

201‧‧‧Microprocessor

2011‧‧‧ button

2012‧‧‧LED digital display

2013‧‧‧Programmable logic gate

2014‧‧‧ memory

202‧‧‧Programmable frequency and waveform and its carrier frequency and waveform generator

203‧‧‧Programmable Power Amplifier

204‧‧‧Programmable Output Exporter

205‧‧‧programmable input device

206‧‧‧Return signal amplifier

207‧‧‧second low pass filter

208‧‧‧Overcurrent detector

209‧‧‧ analog digital converter

Figure 1 is a schematic diagram of a high-medium-low-frequency energy output device and a measuring device for combining skin-to-electrical spectral impedance.

Figure 2 is an energy output device with high, medium and low frequency and its junction. A circuit diagram of a device for measuring the electrical spectral impedance of a skin.

Figure 3 is a schematic diagram of the energy wave (the output frequency, waveform and pause time of the therapeutic radio wave and measurement signal) of the present creation.

Figure 4 is a schematic diagram of the carrier on the main wave of the present creation.

201‧‧‧Microprocessor

2011‧‧‧ button

2012‧‧‧LED digital display

2013‧‧‧Programmable logic gate

2014‧‧‧ memory

202‧‧‧Programmable frequency and waveform and its carrier frequency and waveform generator

203‧‧‧Programmable Power Amplifier

204‧‧‧Programmable Output Exporter

205‧‧‧programmable input device

206‧‧‧Return signal amplifier

207‧‧‧second low pass filter

208‧‧‧Overcurrent detector

209‧‧‧ analog digital converter

Claims (14)

An energy output device having a high, medium, and low frequency, and a measuring device combining a skin to electrical spectral impedance, comprising: an input device for generating a frequency of a main wave and a carrier wave having a predetermined high, medium or low frequency, Input digital data under the indication of waveform, power and pause time; a programmable logic gate for programming hardware logic to control the logical combination of the device; a microprocessor coupled to the input device and the programmable logic a gate, coupled to the microprocessor via a programmed program, for processing and processing the input digital data, and the measured impedance of the processed skin to the electrical spectrum impedance, and outputting the display; a programmable frequency waveform and a carrier frequency waveform generator coupled to the microprocessor, having a digital analog converter and a first low pass filter, the digital analog converter for converting the digital data into an analog waveform signal, and the first low pass The filter is used for filtering the resonant noise, and is configured to generate a programmable waveform of any main wave according to the input digital data, frequency, a first waveform signal of a stop time, a waveform and a frequency of the carrier thereof; a programmable power amplifier coupled to the programmable frequency waveform and a carrier frequency waveform generator for amplifying the power of the first waveform signal Generating a second waveform signal of the most appropriate energy level; a programmable output outputter coupled to the programmable power amplifier for utilization A control signal can be programmed to assign the input of the second waveform signal to output an energy and output an energy signal to a portion of a user's body via a selected first contact member. An energy output device having a high, medium, and low frequency, and a measuring device combined with a skin-to-electrical spectral impedance, as in claim 1, in combination with a skin-to-electrical spectral impedance measuring device, comprising: a programmable input device via The programmable input device selects a second contact member for use in series with the body of the user, and connects another portion of the body via the second contact member to form an electronic circuit at the programmable output distributor. And outputting a first feedback signal: a feedback signal amplifier connected to the first feedback signal of the programmable input device for amplifying the first feedback signal and outputting a second feedback signal; a second low pass filter connected to the feedback signal amplifier for filtering the noise of the second feedback signal to generate a third feedback signal; and an analog to digital converter connected to the second low pass a filter for converting the third feedback signal from the analog signal into a digital output signal and inputting to the microprocessor for processing the data by using the microprocessor; and an output device And an output signal for displaying the result processed by the microprocessor, which represents a metric value of the body's impedance change to the electrical spectrum after the user's body fills the body with high, medium or low cycle energy. An energy output device having a high, medium, and low frequency, and a measuring device combining a skin-to-electrical spectral impedance, as in claim 2, further including an overcurrent detection When the current of the first feedback signal exceeds a predetermined value or the maximum safe current value of the human body, an overcurrent detection signal is output to an overcurrent safety switch of the programmable output output device to be turned off, and simultaneously An overcurrent detection display is sent via the microprocessor. An energy output device having a high, medium, and low frequency, and a device for combining a skin-to-electrical spectral impedance, as claimed in claim 1, wherein the high, medium, and low frequency energy is between 0.01 Hz and 100 MHz. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, as in claim 1, wherein a part of the body of the user is a human body acupuncture. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin to electrical spectral impedance, according to claim 1, further comprising a memory connected to the microprocessor for memorizing the microprocessor Processing data or information about the device's own program. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, as in claim 6, wherein the memory is a flash memory (FROM) or a static memory ( SRAM). An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, as in claim 1, wherein the input device is a button combination. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, as in claim 2, wherein the output device is LED digital display. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, according to claim 1, wherein the first contact member is a conductive patch, a copper pedal, and a copper hand grip Hold the test probe or the drug tray. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin to electrical spectrum impedance, wherein the second contact member is a conductive patch, a copper pedal, and a copper hand grip. Or hold the test stick. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin to electrical spectral impedance, wherein the first waveform signal is a sine wave, a square wave, a triangular wave, an arbitrary waveform, or has Any waveform of the carrier. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin-to-electrical spectral impedance, according to claim 1, wherein the energy output device having a high, medium, and low frequency is used under a safe value for treating a tumor or pain. An energy output device having a high, medium, and low frequency, and a measuring device for combining a skin to electrical spectral impedance, comprising: a programmable input device coupled to a second contact member for selection by a programmable input device a body of the user, and connecting another part of the body via the second contact member, receiving an energy signal from one of the programmable output devices of claim 1 of the patent application, and forming a Outputting a first feedback signal to the electronic circuit; a feedback signal amplifier connected to the first feedback signal of the programmable input device for amplifying the first feedback signal and outputting a second feedback signal; a second low pass filter connected to the a feedback signal amplifier for filtering the noise of the second feedback signal to generate a third feedback signal; and an analog-to-digital converter connected to the second low-pass filter for the third The feedback signal is converted into a digital output signal by the analog signal and input to a microprocessor for processing the data by using the microprocessor; and an output device for displaying an output signal of the result processed by the microprocessor, It represents a measure of the change in impedance of the body to an electrical spectrum after the user's body has added the body to high, medium or low cycle energy.