TH98039A - Methods and systems for coupling signals and blocking direct current. - Google Patents

Abstract

DC60 This section discloses the methods and types of circuit configurations to connect the signals. Low frequencies from one range of the electronics to another, from the outside world to the Or from a range like this to the outside world using a number of double-stack containers More than one which is used in conjunction with other electronic components Such capacitors are used. In transmitting signals while blocking the direct current rather than storing energy. Using a capacitor Two layers instead of conventional capacitors allow a wider range of signal transmission. Very much, with much less distortion. The technology will be fine tuned. It is specially for use in medical devices including bioelectronic stimulation which is prescribed to Redundant devices for safety in the event that a single component fails while it may An unacceptable level of distortion when conventional components are used. This section discloses methods and types of circuit configurations for connecting signals. Low frequencies from one population of electronics to another, from the outside world to the inner This is done from a range like this to the outside by using a double-stack container. More than one which is used in conjunction with other electronic components Such capacitors are used. In transmitting signals while blocking the direct current rather than storing energy. Using a capacitor Two layers instead of conventional capacitors allow a wider range of signal transmission. Greatly reduced with a lot less distortion Such technology will be optimized. It is specially for use in medical devices including bioelectronic stimulation which is prescribed to Redundant devices for safety in the event that a single component fails while it may An unacceptable level of distortion occurs when conventional components are used.

Claims (7)

1. A peripheral circuit consisting of - one conductor having electrical communication with the first external circuit; - the second conducting electrical communication with the second external circuit, and - a two-layer capacitor element between the first conductor. And the second conductor And the A / C electrical signal is connected between the first external circuit and the second external circuit. Where such a double-layer capacitor element has an additional operation that blocks The direct current component of such an A / C electrical signal is predominantly 2. The peripheral circuit according to claim 1, where the double-layer capacitor element It consists of a semiconductor that comes into contact with the electrolyte material 3. Peripheral circuit according to claim 1, where the two-layer capacitor element It consists of one semiconductor that comes into contact with the electrolyte and the semiconductor material. 4. The circuit is connected according to claim 1, where the two-layer capacitor elements are connected to the electrolyte. It consists of more than one double-layer capacitors connected in series. 5. Peripheral circuits according to claim 1, where the double-layer capacitor elements are connected in series. The aforementioned include one or more UTP capacitors. 6. Peripheral circuits according to claim 1 where the A / C electrical signal consists of a charge. 7. The peripheral circuit according to claim 1, which is mentioned above, also contains a resistor with Communicating with a component for a double-layer capacitor, provided that the aforementioned resistor is operated to Improved the impedance coherence between the first external circuit and the second external circuit 8. The peripheral circuit according to claim 1, which, as mentioned above, also consists of a resistor, where Two resistors and capacitive elements can be used to determine the time constant. 9. The peripheral circuit according to claim 1, which has been mentioned above, also consists of a resistor, where The resistors and components for double-layer capacitors produce time constants greater than ten 0. The peripheral circuit according to claim 1, which also includes a resistor. Where The resistors and double capacitor elements produce a time constant with the More than thirty seconds 1 1. Peripheral circuit according to claim 1, which, as mentioned above, also contains a resistor where The resistors and double capacitor elements produce a time constant with the More than one hundred seconds 1 2. Peripheral circuit according to claim 1, which, as mentioned above, also contains a resistor where The resistors and double capacitor elements produce a time constant with the More than a thousand seconds 1 3. Peripheral circuit according to claim 1, which, as mentioned above, also contains a resistor where Resistors and elements for double-layer capacitors produce a frequency of approximately twenty Hz. Or below 1 4. Peripheral circuit according to claim 1, which from the foregoing also contains a resistor where Resistors and double capacitor elements produce an approximate frequency of between five. And fifteen Hertz 1 5. Peripheral circuit according to claim 1 which, as mentioned above, also consists of a resistor where Resistors and double capacitor elements produce approximate frequencies between fractions. Ten thousandth and three-quarter hertz 1 6. Method for connecting the signal between the circuit and the load with a storage element. A two-layer charge consisting of a phase of - a distribution of both alternating current (AC) and direct current (DC) components into the first conductor - diffusion of the signal along the first conductor into the element. For storage Double Charge - Connection of an AC component of a signal through a capacitor element. These two-layered - blocking of the DC component of the signal with the aforementioned double-layer capacitor element, and - the diffusion of the signal containing the AC component from the element for A two-layer capacitor enters the second conductor, and - the transmission of the signal from the second conductor to the load 1 7. Method according to claim 16, where the signal propagation along the first conductor enters the Elements for such a double-layer capacitor have an additional step, namely the coupling of such a signal. Through a single double capacitor 1 8. Method of claim 16, where the propagation of the signal along the first conductor into Elements for such a double-layer capacitor have an additional step, namely the coupling of such a signal. 1 9. Method according to claim 16, where the signaling from the second conductor to the load has a step. Further is the transmission of the signal from the second conductor into the biomaterial 2 0. Method according to claim 16, where the transmission of the signal from the second conductor to the load has a step. Additional is the transmission of the signal from the second conductor into the other circuit. 2 1. A percussion circuit for spreading the A / C signal between two elements. It consists of one or more double-layer capacitor elements that are connected into the The path of the signal current between the two elements where each capacitor is made up of polarity. End, where each terminal of the capacitor, but it acts in a floating state compared to Ground and fixed voltage 2 2. An external circuit according to claim 21, where two components are part of the kit. Electronics, where the path of the current is stretched from one unit. The electronic equipment to another phase 2. 3. Peripheral circuits according to claim 21 where the direction of the path of the signal current. It extends from the external environment to the electronics. 2. 4. Peripheral circuits according to claim 21 where the direction of the path of the said current It extends from the electronics to the external environment. 2. 5. Peripheral circuits according to claim 21, where the direction of the path of the signal current It extends from the electronic device to the biological material 2. 6. Peripheral circuit according to claim 25 where such biological material is combined by human body 2. 7. Peripheral circuit according to claim 25. The aforementioned biological material is incorporated by the animal body 2. 8. Peripheral circuits according to claim 25, whereby such biological material constitutes living organisms. 2 9. peripheral cycle according to claim 25 where such biological material is combined with cells. Biomaterials under culture 3 0. Peripheral cycle according to claim 25 whereby the biomaterial is combined with living tissue. During culture 3 1. The peripheral circuit in accordance with claim 21, where the element for double-layer capacitor It consists of more than one cell connected together in series. 3. 2. The peripheral circuit according to claim 21, which is said to be above, also consists of: For more than one double-layer capacitor, each containing more than one cell that They are connected together in series. 3. 3. Peripheral circuit according to claim 29, where the elements for double-layer capacitors. More than one of them consists of three double-layer capacitors 3 4. Peripheral circuits according to claim 33, where the two-layer capacitor elements are connected to the circuit. More than one contains two-tier capacitors operating within the range. Its nominal voltage 3 5. A peripheral circuit in accordance with claim 21 where the AC signal is accompanied by a component of a DC signal, where the component of such a DC signal consists of a component. 3 6. The peripheral circuit according to claim 35, where the unbalanced charged component is The rule is for a period of time. 3 7. Peripheral circuits according to claim 21, where the assembly for a double-layer capacitor. They are used together with resistors to match the impedance of biomaterial while It retains a time constant which is greater than six seconds. 3 8. Peripheral circuit per claim 37 where the said time constant is greater than thirty seconds. 3 9. Peripheral circuit per claim. At 37 where the aforementioned time constant is greater than 100 s 4 0. Peripheral circuit according to claim 37 where the time constant is greater than 300 s 4. 1. Peripheral circuit according to claim 37 where a time constant is greater than 1000 s 4. 2. Peripheral circuit according to claim 37 where the aforementioned time constant is greater than 3000 s 4. 3. Peripheral circuit according to claim 37 where the aforementioned time constant is greater than 10,000 s. 4. Peripheral circuit according to claim 21, where elements for a double-layer capacitor Such is used in conjunction with a resistor to produce an approximate or less 4 Hertz Intermittent. 5. Peripheral circuit according to claim 21, where elements for a double-layer capacitor It was used in conjunction with a resistor to produce a 4 hertz bias. 6. Peripheral circuit according to claim 21, where elements for a double-layer capacitor It is used in conjunction with a resistor to produce an approximate frequency between five and fifteen Hertz 4. 7. Peripheral circuit according to claim 21, where elements for a double-layer capacitor It is used in conjunction with a resistor to produce an approximate frequency between between one fraction. Ten thousand and three thousand hertz