Abstract: A driver circuit for driving a single conductor line that is coupled to a series of individually controlled circuit units each including a capacitor includes a power supply circuit for supplying a constant current to the single conductor line and a line driver supply circuit configured to modulate a digital information signal onto the constant current on the single conductor tine. The line driver further includes a signaling transistor structured to operate in a zero voltage switched mode at least part of the time, and a signaling inductor coupled between the single conductor line and the signaling transistor.

Abstract: Serial arranged circuits allow multiple different circuit nodes to receive power with a single conductor line carrying current. Data can be transmitted to the serially arranged circuit nodes by modulating the current on the single conductor line. However, switching transistors to modulate current can consume energy. To reduce the switching losses, a double ended driver circuit is disclosed. The doubled ended driver circuit includes switching capacitors and inductors at both ends of a serial string of circuit nodes.

Abstract: In order to control individual circuit nodes coupled to a common serial line, each of the different circuit nodes must be assigned a locally unique address. However, mass manufactured electronics are manufactured as identical electronic devices. Thus, several techniques are presented for assigning unique addresses to identical electronic devices coupled to a common serial line. One set of techniques uses a local sensor that is stimulated in order to specify a single device on the serial line. Another set of techniques measures a pulse presented onto the common serial by a circuit node to determine its relative position on the serial line.

Abstract: A direct current driver circuit for driving a modulated direct current is disclosed. The direct current driver circuit uses a switched capacitor network to keep the circuit operating within carefully prescribed voltage levels in order to reduce energy losses.

Abstract: In order to control individual circuit nodes coupled to a common serial line, each of the different circuit nodes must be assigned a locally unique address. However, mass manufactured electronics are manufactured as identical electronic devices. Thus, several techniques are presented for assigning unique addresses to identical electronic devices coupled to a common serial line. One set of techniques uses a local sensor that is stimulated in order to specify a single device on the serial line. Another set of techniques measures a pulse presented onto the common serial by a circuit node to determine its relative position on the serial line.

Abstract: Serial arranged circuits allow multiple different circuit nodes to receive power with a single conductor line carrying current. Data can be transmitted to the serially arranged circuit nodes by modulating the current on the single conductor line. However, switching transistors to modulate current can consume energy. To reduce the switching losses, a double ended driver circuit is disclosed. The doubled ended driver circuit includes switching capacitors and inductors at both ends of a serial string of circuit nodes.

Abstract: To control multiple electronic circuits organized in a series configuration, this document introduces a single-wire power, control, and feedback system. Specifically, individually controlled electronic circuits are arranged in a series configuration that is driven by a control unit located at the head of the series. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the electronic circuits in the series in a manner that allows each electronic circuit to periodically draw power from the single wire and receive control information. Each electronic circuit in the series may communicate back to the head-end control unit by drawing power or not during a specified time slot.

Abstract: Data may be encoded onto a direct current power line by modulating the current on that direct current power line. One method of modulating the current is by placing an inductor on the power line and then using a controlled transistor that turns on and turns off. The inductor will ensure that current keeps flowing but the transistor will induce changes in the current pattern. The excess current from when transistor is turned off must be diverted. Furthermore, to create symmetrical current changes, the inductor should be reverse biased. Thus, a circuit is created that sinks the excess current from when the transistor is turned off and used to reverse bias the inductor.

Abstract: Electrical power is traditionally transmitted with high-voltage alternating current transmission lines. For some limited applications, high-voltage direct current is used to transmit electrical power since direct current transmission is much more efficient. However, due to the high costs of high-voltage alternating to high-voltage direct current conversion equipment, direct current transmission is rarely use. To provide direct current electrical transmission at a reduced cost, a loop-based direct current transmission system is disclosed. The loop-based direct current system operates by carrying direct current in a loop that coupled individual power consumer and power generating nodes. Each node can add voltage to or subtract voltage from the current loop.

Abstract: To power and control multiple different electronic circuit nodes, this document introduces a single-wire multiple-circuit power and control system. Specifically, individually controlled circuit node units are arranged in a series configuration that is driven by a power and control unit located at the head of the series. Each of the individually controlled circuit node units may comprise more than one output circuit that is also individually controllable. The head-end power and control unit provides both electrical power and control signals down a single wire to drive all of the individual circuit node units in the series in a manner that allows each individual circuit node unit to be controlled individually or in assigned groups.

Abstract: Data may be encoded onto a direct current power line by modulating the current on that direct current power line. One method of modulating the current is by placing an inductor on the power line and then using a controlled transistor that turns on and turns off. The inductor will ensure that current keeps flowing but the transistor will induce changes in the current pattern. The excess current from when transistor is turned off must be diverted. Furthermore, to create symmetrical current changes, the inductor should be reverse biased. Thus, a circuit is created that sinks the excess current from when the transistor is turned off and used to reverse bias the inductor.

Abstract: A broadband data broadcast system that allows rich multimedia content to be delivered to a plurality of subscribers is disclosed. The broadband data broadcast system operates by multiplexing a plurality of rich multimedia digital information streams together at a centralized data broadcast center. The data broadcast center then broadcasts the multiplexed digital information stream on a broadcast medium such as satellite broadcasts, radio frequency broadcasts, or digital television broadcasts. A large number of receiver systems receive the broadcast signal and demodulate the broadcast signal to retrieve the multiplexed digital stream. The receiver system extracts a subset of digital information streams that the particular receiver system's owner has designated are of interest. The receiver system caches the interesting digital information stream for later access. The receiver system outputs the interesting digital information streams to a client system upon demand.

Abstract: To power and control multiple different electronic circuit nodes, this document introduces a single-wire multiple-circuit power and control system. Specifically, individually controlled circuit node units are arranged in a series configuration that is driven by a power and control unit located at the head of the series. Each of the individually controlled circuit node units may comprise more than one output circuit that is also individually controllable. The head-end power and control unit provides both electrical power and control signals down a single wire to drive all of the individual circuit node units in the series in a manner that allows each individual circuit node unit to be controlled individually or in assigned groups.

Abstract: To control multiple electronic circuits organized in a series configuration, this document introduces a single-wire power, control, and feedback system. Specifically, individually controlled electronic circuits are arranged in a series configuration that is driven by a control unit located at the head of the series. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the electronic circuits in the series in a manner that allows each electronic circuit to periodically draw power from the single wire and receive control information. Each electronic circuit in the series may communicate back to the head-end control unit by drawing power or not during a specified time slot.

Abstract: To control multiple electronic circuits organized in a series configuration, this document introduces a single-wire power and control system. Specifically, individually controlled electronic circuits are arranged in a series configuration that is driven by a control unit located at the head of the series. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the electronic circuits in the series in a manner that allows each electronic circuit to periodically draw power from the single wire. Each electronic circuit in the series has been designed such that the electronic circuits coordinate power draws to reduce peak power demand.

Abstract: Direct current circuits always require a voltage source consisting of a positive voltage and a ground. To power a plurality of a direct current circuit nodes one must traditionally supply a power supply line and a ground line to each circuit node. To simplify wiring, a single conductor system of powering a plurality of circuit nodes is disclosed wherein each circuit node has only two external connections and the circuit nodes are coupled in series. Specifically, each individual circuit node has an integrated circuit and a capacitor. A power circuit within the integrated circuit then directs current from an input into the capacitor to create a local power supply and shunts current from the input to an output when not directing current into the capacitor.

Abstract: An controlled LED lighting system that operates using a single conductor to power and control LED nodes is disclosed. The controlled LED lighting system modulates control data onto a nominally constant DC signal transmitted down a single conductor serial line. Nodes coupled the serial line draw power into a local capacitor and demodulate the data signal. Each node shunts the serial line when additional power is not required such that the data signal is received by every node on the serial line.

Abstract: Light Emitting Diodes (LEDs) are increasingly used in illumination applications. To control multiple Light Emitting Diodes (LEDs), or any other controllable light source, this document introduces a single-wire multiple-LED power and control system. Specifically, individually controlled LED units are arranged in a series configuration that is driven by a control unit located at the head of the series. Each of the individually controlled LED units may comprise more than one LED that is also individually controllable. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the LED units in the series in a manner that allows each LED unit to be controlled individually or in assigned groups.

Abstract: Light Emitting Diodes (LEDs) are increasingly used in illumination applications. To control multiple Light Emitting Diodes (LEDs), or any other controllable light source, this document introduces a single-wire multiple-LED power and control system. Specifically, individually controlled LED units are arranged in a series configuration that is driven by a control unit located at the head of the series. Each of the individually controlled LED units may comprise more than one LED that is also individually controllable. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the LED units in the series in a manner that allows each LED unit to be controlled individually or in assigned groups.

Abstract: Light Emitting Diodes (LEDs) are increasingly used in illumination applications. To control multiple Light Emitting Diodes (LEDs), or any other controllable light source, this document introduces a single-wire multiple-LED power and control system. Specifically, individually controlled LED units are arranged in a series configuration that is driven by a control unit located at the head of the series. Each of the individually controlled LED units may comprise more than one LED that is also individually controllable. The head-end control unit provides both electrical power and control signals down a single wire to drive all of the LED units in the series in a manner that allows each LED unit to be controlled individually or in assigned groups.