JP2019169475A - System having series configuration to be controlled in digital manner - Google Patents

Abstract

To provide an electronic illumination system based on a light emitting diode and a method for driving the light emitting diode.SOLUTION: An illumination control system including a power supply 210 for generating rated constant current receives input data and processes the input data to create control data 231 for driving an LED 250. The illumination control system comprises: a modulator circuit for superposing the control data 231 on the rated constant current to perform modulation; and a plurality of LED driver nodes that have a single port and a single output port and receive the rated constant current. Each of the plurality of LED driver nodes comprises: a local capacitor; a power sub circuit that periodically directs the rated constant current received via the input port to the local capacitor to generate a local power supply and, in the case of not directing the rated constant current to the local capacitor, shunts the rated constant current to the output port; a data extraction sub circuit for demodulating the rated constant current to obtain the control data; and an LED driver circuit 220 to be controlled using the control data.SELECTED DRAWING: Figure 2A

Description

  The present invention relates to the field of electronic systems arranged in series. In particular, the present invention discloses a technology for supplying electric power and a control signal to drive an electronic component such as a light emitting diode in series wiring, but is not limited thereto.

  Light emitting diodes (LEDs) are very efficient electronic light sources. Early LEDs emitted red light with low lighting power. However, modern LEDs can emit light over visible, ultraviolet and infrared wavelengths. Moreover, modern LEDs can be supplied with a substantial amount of current to produce enough light for the LED to use as a light source.

  LEDs have many advantages over conventional light sources such as energy efficiency, long life, high durability, small form factor, and fast switching. Many of these advantages have facilitated the use of LEDs in a wide range of applications. However, compared with conventional incandescent and fluorescent light sources, LEDs still have a relatively high initial cost. In addition, LEDs generally require more accurate current and thermal management than conventional light sources. The first generation LED was mainly used as an indicator lamp for electronic equipment. LEDs have been made ideal for portable electronic devices because of their low energy consumption and small form factor. However, in recent years, new LED colors and brightness improvements have enabled LEDs to be used in many new applications.

  The small size of the LED and the ability to perform switching control using a digital control system has made it possible to develop LEDs based on display systems. In particular, words and images can be displayed using a two-dimensional array of individually controlled LEDs. Thus, LEDs have become the light source for many currently used electronic bulletin boards and super-large video display systems such as the large video display systems found in sports arenas and Times Square in New York City.

  Although LED-based display systems have proven to be highly functional, the widespread use of LED-based video display systems due to the inherent difficulties and costs associated with the manufacture of such LED-based video display systems and the like Has been suppressed. Carefully measured and individually controlled power must be supplied to each LED in the two-dimensional array of LEDs that form the LED-based video display system. Building a monochrome high-definition display system with a resolution of 1920 × 1080 image elements (pixels) requires that the system supply carefully controlled power to 2,073,600 LEDs. Creating a multi-color high-definition display system requires three different colors (red, green, blue) for each pixel, so 6,220,800 LEDs each need to receive carefully controlled power. is there. Therefore, such a large video display system is complicated and expensive to design and manufacture.

  LED-based large video display systems cost millions of dollars due to the challenge of controlling a large number of LEDs separately, resulting in large LED-based video displays only for very high-end applications such as large sports arenas The system cannot be purchased. Public video display systems in other situations typically use smaller than conventional display technologies associated with television displays or team scores and game times on large electronic bulletin boards that use a pre-defined array of LED patterns. Use a much simpler display system, such as the one used to display It is therefore desirable to simplify the task of designing and building LED-based displays and lighting systems.

  The drawings are not necessarily to scale, like numerals refer to substantially equivalent elements throughout the several views. Those with the same reference and different subscripts indicate different examples of substantially equivalent elements. The drawings are generally described by way of example of various embodiments addressed herein, but are not intended to be limiting.

FIG. 6 is a block diagram of an example machine in the form of a computer system capable of executing a set of instructions that cause the machine to perform one or more methods described herein. 1 is a block diagram illustrating an overall architecture of a single-wire multiple LED unit control system according to the present disclosure. FIG. It is a figure which shows an example of the data packet which can be transmitted to a LED unit. FIG. 6 is a timing diagram of digital information modulated as a deviation of a current ramp from a rated current value. It is a timing diagram of digital information modulated as a deviation of a sine curve before and after a rated current value. FIG. 6 is a timing diagram of digital information modulated as a deviation of a current dip from a rated current value. It is a figure which shows the LED line driver circuit of 1st Embodiment. It is a figure which shows the LED line driver circuit of 2nd Embodiment. It is a figure which shows a mode that an LED line driver circuit raises the lamp | ramp of a line current by turning on an external field effect transistor. It is a figure which shows a mode that an LED line driver circuit turns off an external field effect transistor, and falls the lamp | ramp of a line current. FIG. 6 is a diagram illustrating a current modulated by the circuits of FIGS. 5A and 5B. FIG. 3 shows ideal symmetric current pulses and non-ideal current pulses. It is a graph which shows a mode that a computer performs the timing which switches FET. FIG. 6 shows a timeline of stages during a single data bit period. FIG. 5 is a diagram showing a lamp mode modulated current signal when energy is saved by reducing the rated current level. It is a figure which shows one Embodiment of the LED unit controlled separately. It is a flowchart which shows a mode that the power supply system of the LED unit controlled separately is operated. FIG. 6 is a diagram showing data periods resulting in incorrect alignment in ramp mode modulation. It is a figure which shows the data period which resulted in the incorrect arrangement | sequence by dip mode modulation. It is a figure which shows the pulse produced | generated by the conventional pulse width modulation, and the figure which shows the pulse produced | generated by the flicker mitigation modulation system. Figure showing the output pattern generation result of flicker mitigation modulation, figure showing incomplete current pulse and ideal square pulse, after performing various randomizations to rearrange the pulses, perform flicker mitigation modulation of Figure 10C It is a figure which shows the data pattern. FIG. 3 is a block diagram illustrating a first LED lighting system that may be made based on the teachings of the present disclosure. It is a figure which shows the LED lighting system of FIG. 11A which controls a some LED lighting installation with a single controller. FIG. 3 is a block diagram illustrating a second LED lighting system that may be made based on the teachings of the present disclosure. 1 is a diagram illustrating an LED drive system of the present disclosure implemented as a stage lighting system based on a DMX512-A protocol. FIG. FIG. 6 is a diagram showing an application example in which a single LED line driver circuit drives 64 individually controlled LED units arranged in an 8 × 8 array. It is a figure which shows the concept of a mode that a large two-dimensional display system is produced combining a small module type two-dimensional array (shown in FIG. 14). It is a figure which shows a mode that several strings of the LED unit controlled separately is suspended in parallel with each other, and a 2D display system is produced. FIG. 6 is a flow chart showing a method for arranging, calibrating and operating a display system made from a plurality of strings of LED units. FIG. 6 is a data flowchart showing how an input video signal is decoded, processed by a model of an LED display system, and an LED control command for driving a display system produced by arranging a set of LED strings is generated.

  The following detailed description includes references to the accompanying drawings, which form a part of the specification. The drawings are in accordance with exemplary embodiments. These embodiments are also referred to herein as “examples” and are described in sufficient detail to enable those skilled in the art to practice the invention. It will be apparent to those skilled in the art that the specific details in the exemplary embodiments are not necessary to practice the invention. For example, although the exemplary embodiments primarily disclose a system that effectively transmits power and data to control a light emitting diode (LED), the teachings of this disclosure transmit power and data and otherwise Can be used to control any type of electronic equipment. The exemplary embodiments can be combined, other embodiments can be used, and structural, logical, and electrical changes can be made without departing from the scope of the claims. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope is defined by the appended claims and their equivalents.

  As used herein, the term “a” or “an” is used to include one or more, as commonly used in patent documents. The term “or” is used herein to denote a non-exclusive meaning, ie, “A or B”, unless otherwise specified, “A instead of B”, “ It includes the meanings of “B” instead of “A”, “A and B”. Furthermore, all publications, patents and patent documents cited herein are hereby incorporated by reference in their entirety as if individually incorporated by reference. In the event that the use in this specification and the use in these references thus incorporated by reference are inconsistent, the use in the incorporated reference should be considered as complementary to the use herein. That is, inconsistencies that do not match are restricted to use in this specification.

TECHNICAL FIELD This disclosure relates to computer systems because computer systems are generally used to control LED lighting and display systems. FIG. 1 is a block diagram illustrating a machine in an example form of a computer system 100, which may partially implement the present disclosure. Within computer system 100 is an instruction set 124 that, when executed, can cause a machine to perform one or more of the methods described herein. In a networked deployment, the machine can operate within a server machine or client machine capacity in a client-server network environment, or as a peer machine in a peer-to-peer (or distributed) network environment. The machine can be a personal computer (PC), a tablet computer, a set top box (STB), a personal digital assistant (PDA), a mobile phone, a web appliance, a network router, a switch or bridge, or a computer that specifies the action that the machine takes. Any machine that can execute an instruction set (continuous or not). Further, although only a single machine is illustrated, the term “machine” may be used to execute one instruction set (or multiple instruction sets) individually or jointly, as described herein. Suppose we include any set of machines that perform the method.

  The example computer system 100 includes a processor 102 (eg, a central processing unit (CPU), a graphics processing unit (GPU), or both), a main memory 104, and a static memory 106, which communicate with each other via a bus 108. . The computer system 100 may further include a video display adapter 110 that drives a video display system 115 such as a liquid crystal display (LCD) or a cathode ray tube (CRT). The computer system 100 also includes an alphanumeric input device 112 (eg, a keyboard), a cursor control device 114 (eg, a mouse or trackball), a disk drive unit 116, an output signal generator 118, and a network interface device 120.

  The disk drive unit 116 includes a machine-readable medium 122 that includes one or more computer instructions that implement or be utilized by one or more methods or functions described herein. Stores sets and data structures (eg, instructions 124 known as “software”). The instructions 124 may also be wholly or at least partially in the main memory 104 and / or in the processor 102 executing by the computer system 100, which may constitute a machine-readable medium. is there. It should be noted that the illustrated computer system 100 is only one possible example, and other computers do not have all of the components shown in FIG.

  The instructions 124 may further be sent and received over the computer network 126 via the network interface device 120. Such transmission can be performed using any one of a number of known transfer protocols, such as file transfer protocol (FTP).

  Although the machine-readable medium 122 is illustrated as a single medium in the exemplary embodiments, the term “machine-readable medium” refers to a single medium or multiple media (eg, a central medium) that stores one or more instruction sets. Database and / or its associated cache and server). The term “machine-readable medium” can also be stored, encoded, or transmitted by a machine to be executed by a machine, causing the machine to perform or do one or more of the methods described herein. It should also be considered to include any medium that can be used to store, encode or transmit data structures used by or associated with this instruction set. Thus, the term “machine-readable medium” should be considered to include, but is not limited to, solid state storage devices, optical media, and magnetic media.

  For the purposes of this specification, the term “module” refers to a code, an instruction that can be calculated or executed, data, or an identifiable portion of a calculation object to achieve a particular function, operation, process, or procedure. Including. There is no need to implement modules in the software. That is, a module may be mounted on software, hardware / circuit, or a combination of software and hardware.

  In the present disclosure, the computer system may include an ultra-small microcontroller system. The microcontroller is a single integration that contains the four major components that make up the computer system: an arithmetic logic unit (ALU), a control unit, a memory system, and an input / output system (collectively referred to as I / O). A circuit can be provided. Microcontrollers are extremely small and low cost integrated circuits and are very often used in digital electronics.

Overview of Control System for Controlling Multiple LEDs To control multiple light emitting diodes (LEDs) or any other controllable electronics (such as other types of electronic light sources), it is herein connected in a series configuration. A single-wire power supply and control system for a plurality of units is disclosed. In particular, in one embodiment, the individually controlled electronic units that control the LEDs are arranged in a series configuration and driven by a control unit located within the series configuration. A separate series of electronic units that are individually controlled may be referred to as a “line” or “string” of lighting devices. The control unit used to supply power and data to a series of electronic units may be referred to as a “line driver”, “string driver”, or “head end controller”. This is because the control unit provides power and control signals to drive all individually controlled electronic units on a line or string. Although the present disclosure focuses on controlling LEDs or other light sources, the teachings of the present disclosure are intended to control any other electronic device such as an acoustic system, motor, sensor, camera, liquid crystal display (LCD), etc. May be used.

  FIG. 2A is a block diagram illustrating the overall architecture of a single-wire, multiple LED unit control system constructed using the teachings of this disclosure. The LED line driver circuit 220 is installed in a series of individually controlled LED units (250-1 to 250-N). In the exemplary embodiment of FIG. 2A, the LED line driver circuit 220 receives power from the external power supply circuit 210, which will be described in detail later herein. The LED line driver circuit 220 also receives LED control data from the master LED controller system 230. (Although also described herein as an “LED line driver circuit,” the line driver circuit sends power and data to other types of circuits connected to the driver line that perform operations other than controlling the LEDs. Note that can be used for

  The master LED controller system 230 provides a method for turning on and off various LEDs in individually controlled LED units (250-1 to 250-N) on the string, and the brightness of each LED that is turned on. Provides detailed control data describing In one embodiment, the master LED controller system 230 provides color values and brightness because each individually controlled LED unit 250 has multiple LEDs of different colors.

  The master LED controller system 230 may be any type of digital electronic system that provides LED control data to the LED line driver circuit 220 in an appropriate format. The master LED controller system 230 can range from simple single chip microcontrollers to advanced computer systems that coordinate and drive multiple LED strings. For example, in a relatively simple embodiment, a master LED controller system 230 with microcontroller components, a power supply 210, and an LED line driver circuit 220 are combined into a single LED driver circuit system 239 that controls a string of LED units 250. Can be incorporated into In a more advanced embodiment, an external computer system, such as the computer system 100 as shown in FIG. 1, is connected to the LED line driver circuit 220 using a signal generator 118 or any other suitable data output system. It can be programmed to output a control data signal.

  In one particular embodiment, LED control data 231 is provided from the master LED controller system 230 to the LED line driver circuit 220 using a known serial peripheral interface (SPI). In this manner, many LED strings can be connected to a single master LED controller system 230, such as computer system 100, thereby controlling these LED strings. However, in alternative embodiments, other suitable digital communication systems such as Universal Serial Bus (USB), Ethernet, or IEEE 1394 interface (Fire Wire) may be used to transmit LED control data to the LED line driver circuit 220. Can be used to provide. In an embodiment intended for use for stage lighting, the data interface can be programmed to accommodate the well-known DMX512-A protocol used to control stage lighting. In such an embodiment, multiple LED line drivers can be connected in a daisy chain configuration to control multiple strings of individually controlled LED units.

  Using the power 211 received from the power supply 210 and the LED control data 231 received from the master LED controller system 230, the LED line driver circuit 220 allows the LED units (250-1 to 250-N) to be individually controlled. The electronic signal is driven in a current loop (consisting of a line starting at 221 and returning to 229) that supplies both power and control data to the entire string. This system of supplying both power and control data on a single line greatly simplifies the design and construction of LED lighting and display systems. In addition, by using a single line to transmit both power and control data, the construction cost of a display or lighting system using multiple LEDs is greatly reduced. With the disclosed system, a single current loop (also referred to as a driver line) allows seven or more different functions for individually controlled LED units on the string, eg, (1) to LED unit 250 Power, (2) control and configuration commands to LED unit, (3) LED output data, (4) clock reference value used to generate local clock signal, (5) calibrate current output to LED Functions such as (6) heat dissipation, and (7) physical structure supporting individually controlled LED units (250-1 to 250-N). Details of each function are described in later sections of this specification.

  FIG. 2B illustrates one embodiment of a data frame that can be modulated on a driver line that is linked to individually controlled LED units (250-1 to 250-N). The head of the data frame is a synchronization byte 291. Since there is no separate clock signal sent to the LED unit 250, the LED unit 250 uses the sync byte to assist in tracking the digital data signal and determine the starting point for each new data frame. The command field 292 then specifies a specific command to be executed by the receiving LED unit 250. An address field 293 designates a specific address (or address group) and selects the LED units (250-1 to 250-N) responding to this command. Following the address field 293 is a data field 294 containing the payload of the data. Finally, an optional cyclic redundancy check (CRC) code 295 may be used to perform data integrity.

  Referring again to FIG. 2A, a number of individually controlled LED units (250-1 to 250-N) are connected to a driver line in a series configuration (starting at 221 and returning to 229). Each individually controlled LED unit 250 includes one or more LEDs, an LED control circuit, and other additional components necessary to complete the individually controlled LED unit 250. In one embodiment, the only additional electronic components required for each LED unit 250 are an LED control circuit and a capacitor that stores electrical energy storage for driving the LEDs of the individually controlled LED unit 250. In other embodiments that handle even larger amounts of current, external diodes and small heat sinks may be used in addition to the capacitors used to store electrical energy. When there are two or more LEDs connected to the individually controlled LED unit 250, the different LEDs of the LED unit 250 are referred to as LED “channels” of the LED unit 250, respectively.

  In some embodiments, two or more capacitors can be used to store power for operating the individually controlled LED unit 250. For example, in one embodiment, different capacitors are used to store power for different LEDs. This is because the different color LEDs operate at different voltage levels, and by combining a capacitor for each different color LED, the net required to drive a specific color LED using this capacitor is achieved. This is because it is possible to store only the voltage amount. In this method, a high voltage amount is supplied to an LED that requires a high voltage amount, but a low voltage amount is supplied to an LED that requires a low voltage amount. This prevents the voltage drop circuit from being used inefficiently and simply consuming excess voltage as waste heat.

  An important component in each individually controlled LED unit (250-1 to 250-N) is an LED controller circuit. The LED controller circuit performs most of the tasks necessary to reasonably control the various LEDs of the individually controlled LED unit 250. These tasks include obtaining electrical energy from the driver line, storing this electrical energy in a power capacitor used to power the LED unit, and adjusting the voltage required to power the LED controller circuit. Producing, demodulating the data signal modulated by the driver line, decoding the demodulated data signal to obtain the data frame, executing the command received in the data frame, and various LEDs with specific brightness This includes driving by level. Details of each of these functions are described in the section of individually controlled LED units.

LED Line Driver As described in the above section, the LED line driver circuit 220 of FIG. 2A is a driver line that starts at 221 and returns to 229, with individually controlled LED units (directly connected to the LED line driver circuit 220). 250-1 to 250-N) to supply both power and LED control data to all. In order to make the construction of the LED lighting / display system simple and inexpensive, the LED line driver circuit 220 supplies both power and control data to all the LED units 250 in a single driver line. This single-line driver line greatly simplifies the construction of a lighting / display system that uses a large number of individually controllable lighting elements. This is because a simple daisy chain configuration connected by a single wire can be used.

  In order to supply power to the individually controlled LED unit 250, the LED line driver circuit 220 functions as a current source that drives a direct current (DC) signal with a single driver line. In some embodiments, the DC signal is driven at a nominally constant level. However, the main purpose is to provide a data signal that can be tracked by each LED unit 250 and a current sufficient to supply energy to the LED unit 250. Each individually controlled LED unit (250-1 to 250-N) connected to the driver line in a series configuration demodulates the data from the DC current signal and performs the necessary operation from the DC current signal driven by the driver line. Pull out power.

  In order to provide LED control data to all individually controlled LED units 250 on the string, the LED line driver circuit 220 modulates the data with a current driven by the driver line. Various different methods may be used as the data modulation method. Although two different methods used are described herein, other data modulation systems may be implemented as will be understood by those skilled in the art.

  In one embodiment, the line driver circuit modulates data on the driver line by using a current ramp that goes slightly above and below the rated current level. In such an embodiment, each data bit period is divided into two cycles that include either a positive current ramp followed by a negative current ramp or a negative current ramp followed by a positive current ramp. be able to. These two different data patterns can be used to represent “1” or “0” for digital communication systems. FIG. 3A is a graph showing a current of a driver line controlled by the LED line driver circuit 220 when data is modulated with a current. In the example of FIG. 3A, a logical “0” indicates that a positive current ramp is followed by a negative current ramp, and “1” indicates that a negative current ramp is followed by a positive current ramp. Note that the average current value on the line is the rated current level 310 because the content of each data phase includes both positive and negative current ramps. FIG. 3B shows a similar embodiment using sinusoidal current changes around the rated current level 310.

  Other data encoding means include those using Manchester encoding and Non-Return-To-Zero using Manchester. Other means of modulating data with current may be used. For example, in an alternative embodiment, a first current level can be used to specify a logical “0” and a second current level can be used to specify a logical “1”. . In this way, a stream of data bits can be encoded by switching between two current levels.

  FIG. 3C shows another data modulation system referred to as “dip mode” modulation. In the dip mode modulation system shown in FIG. 3C, each data bit period is divided into a first half and a second half. The modulation system then modulates the data by generating a current dip in either the first half or the second half of the data bit period. In the particular embodiment of FIG. 3C, a data bit of “0” indicates that a current dip has occurred in the first half, and a data bit of “1” indicates that a current dip has occurred in the second half. Examples of modulation circuits for the ramp mode and dip mode data modulation systems shown in FIGS. 3A and 3C, respectively, will be described.

First LED Line Driver Circuit Embodiment Using Lamp Mode FIG. 4A is a block diagram illustrating the nature of LED line driver circuit 425 for an embodiment that modulates data using the system shown in FIG. 3A. The LED line driver circuit 425 of FIG. 4A implements a current modulation system called “lamp mode” modulation. The lamp mode modulation system is designed for a low cost implementation that can modulate data using one LED line driver IC 420, one field effect transistor (FET), one dielectric, and several resistors. It has been done.

  The main component of the LED line driver circuit 425 is an advanced LED line driver IC (integrated circuit) 420 that controls the overall operation of the LED line driver circuit 425. The LED line driver IC 420 includes a clock circuit block 485 for generating a clock signal necessary for driving the digital circuit. Clock circuit block 485 receives input from an external clock 486 (or resonator) and generates the various internal clock signals required. The clock circuit block 485 includes a prescaler to reduce the speed of the clock signal sent from the external clock 486 for internal core clock generation, a number of synchronous logic circuits that ensure that the chip clock is correctly started after power reset, and A timing generator may be provided for transmitting data modulated on the driver line at the correct data rate.

  Looking at the lower left of the LED line driver IC 420 of FIG. 4A, the data interface 430 is receiving control data from an external controller such as the master LED controller system 230 shown in FIG. 2A. The data interface 430 extracts input control data and transfers this control data to the command parser and handler circuit 440. In a simple embodiment, the LED line driver IC 420 itself may include a circuit that generates a pattern of LED control data and does not require an external LED controller.

  In one particular embodiment, the data interface 430 implements a well-known serial peripheral interface (SPI) protocol. The SPI implementation typically includes the standard data in 432, data out 431, data clock (not shown), and chip select (not shown) pins used by the serial peripheral interface (SPI) protocol. Also good. The behavior of the SPI system varies depending on the particular implementation. In a conventional SPI implementation, an external SPI master (such as the master LED controller system 230 of FIG. 2A) sends data to the data line 432 of each LED line driver IC 420, and which LED line driver circuit is associated with each LED line driver IC. Specifies whether to act on the data by activating the chip select pin. Since the SPI protocol is a bi-directional protocol, individual LED line driver circuits can send status information back to an external SPI master system. One embodiment of the LED line driver circuit uses a return data path for returning a response to a status query such as a request for calibration information and buffer status. In an alternative implementation of the SPI protocol, the data-out 431 line can be connected to the data-in interface of another LED line driver circuit in a daisy chain configuration, so a series of LED line driver circuits can be connected to a single master LED controller system. Can be controlled.

  The command parser and handler circuit 440 verifies the input control data and reacts appropriately to the input control data. In one embodiment, the LED line driver IC 420 routes driver lines to three main types of input commands (configuration requests, status requests, and individually controlled LED units connected to this driver line. Request to transfer data down). The configuration request can instruct the LED line driver IC 420 to set the designated control register in the control and status register block 441. The configuration request can also instruct the LED line driver IC 420 to blow the non-volatile configuration fuse of the LED line driver IC 420 and program the LED line driver IC 420 with permanent configuration information. The input status request can request status information such as a buffer status, an operation status, and a current configuration from the LED line driver IC 420. Such a status request sent to the LED line driver IC 420 may be processed by fetching information from the control and status register 441 and sending a response to the master controller on the data outline 431.

  The request sent from the master LED controller to the LED line driver IC 420 to transfer the LED control data from the driver line to the individually controlled LED unit generally occupies most of the communication with the LED line driver IC. The command parser and handler circuit 440 processes these LED control data, transferring the request by transferring the LED control data to the line data transmission block 450. The line data transmission block 450 stores the control data in the frame buffer. In the embodiment of FIG. 4A, since the LED line driver IC 420 includes two frame buffers (451 and 452), the LED line driver IC 420 receives the LED control data input from the master LED controller to the first frame buffer. While it can be received, the LED control data sent from the second frame buffer is simultaneously modulated on the driver line. The frame buffers (451 and 452) temporarily store LED control data for one or more individually controlled LED units (470-1 to 470-N) connected to the driver line.

  In some embodiments, the LED unit 470 can communicate back to the LED line driver IC 420. For example, since the LED unit 470 can send a signal back to the LED line driver IC 420 by turning on / off the shunt transistor at a specified time period, the LED line driver IC 420 can detect the effect. . In such an embodiment, a status request message input to the data-in 432 can request status from individually controlled LED units 470 connected to the driver line. The command parser and handler circuit 440 then translates this LED unit status request into a second status request message, which is then sent to the line data transmission block 450 and modulated on the driver line. When receiving a response from the LED unit 470, the LED line driver IC 420 sends a corresponding response message to the data outline 431.

  The line data transmission block 450 is responsible for transmitting LED control data (and status requests in some embodiments) to the LED unit 470 on the driver line. The line data transmission block 450 retrieves the control data (or status request) transferred to this block from the command parser and handler circuit 440 and fills the next available frame buffer. In one embodiment, the line data transmission block 450 can calculate a cyclic redundancy check (CRC) byte, which is an optional frame (if the control register 441 specifies to do so). In one embodiment, if there is no pending LED control data (or status) in the line data transmission block 450 to modulate on the driver line, the line data transmission block 450 modulates an idle data frame on the driver line. Idle data frames are not subject to any individually controlled LED units 470, but these individually controlled LED units 470 maintain synchronization with the driver stream modulated data stream. To assist.

  The line data transmission block 450 transfers the formatted data frame from the frame buffers (451 and 452) to the current modulation block 490. The current modulation block 490 serves to modulate a (nominally) constant DC current signal with the driver line and provide a data stream to the LED unit 470 on the driver line. In particular, the current modulation block 490 modulates the current by increasing or decreasing the current short and abruptly, and transmits LED control data downstream of the driver line to control the LED unit 470. In one embodiment, the current modulation block 490 achieves this goal by controlling an external transistor that biases the inductor at the driver line.

  Before describing the current modulation block 490 in more detail, it is helpful to outline the power source. Most electronic circuits are configured to power the electronic circuit using voltage force as a power source. An ideal voltage source is a conceptual mathematical model that can produce infinite current at a specially set voltage level to drive a load circuit and has zero internal resistance. Of course, a real-world voltage source such as a battery or a DC power source cannot produce an infinite current, and the internal resistance does not become zero. However, as long as the load circuit powered by the real-world voltage source does not exceed the current capacity of the real-world voltage source and adds a non-zero internal resistance in series with the load circuit, the ideal voltage for the circuit modeling the voltage source Source can be used.

  When designing electronic circuits, there are far fewer ways to use a current source to model a power source. An ideal voltage source is a mathematical model of a power source that has infinite internal resistance and can produce an infinite voltage at a specific current level to drive a load circuit. Similarly, no real-world current source can supply an infinite voltage, and no real-world current source has infinite resistance. However, unless the overall resistance of a load circuit driven by a real-world current source is too high to require very high voltage values, an ideal with an infinite internal resistance connected in parallel with an ideal current source Real-world current sources can be modeled as current sources (circuits known as Norton equivalent circuits). In the present disclosure, a current source is used as a power source model. In particular, the LED line driver IC 420 and the current modulation block 490 of the supporting external circuit may also be used to drive current in the driver line, specifying an adjustable rated level during operation. Furthermore, the current modulation block 490 varies the current level around a specific rated current value by slightly increasing or decreasing the current, and the rating used to modulate the data with the current as described in FIGS. The current value can be varied away from the current value.

  Referring again to FIG. 4A, the external power source 410 produces a current that is transmitted through the LED unit 470 downstream of the driver line. The output voltage of the external power supply 410 at the head of the driver line (denoted as Vsupply 411) is a potential that is higher than the total required for all the LED units 470 on the driver line. The current passes through all LED units 470 on the string and then flows to ground through inductor 462 and field effect transistor (FET) 461. Current modulation block 490 carefully modulates the current level on the driver line by controlling inductor 462 using FET 461 to generate the modulated current pattern shown in FIG. 3A. It should be noted that the FET 461 is generally mounted outside the LED line driver IC 420 because the FET 461 can handle a relatively high potential that cannot be processed in a normal CMOS semiconductor.

  Referring again to the current graph shown in FIG. 3A, the driver line current varies slightly above and below a constant rated current value 310 used to modulate data in the driver line, resulting in a constant rated current value. Modulated around 310. 5A, 5B, and 5C show how the LED line driver circuit uses the FET 561 to modulate the current around the specified rated current value 310 to control the inductor 562. FIG. Note that current control circuits other than FETs may be used instead.

  In a steady state direct current (DC) circuit, the inductor acts as a short circuit without affecting the circuit. However, when the state changes, the inductor counters the change in current level. Thus, as the current through the inductor increases, the inductor delays the increase in current by storing energy in a magnetic field. Similarly, as the current through the inductor decreases, the inductor counters the current decrease by using energy stored in the magnetic field and supplements the decelerating current.

  Referring to FIG. 5A, when the LED line driver circuit 425 is first turned on, the LED line driver circuit turns on the FET 561 and current flows downward from the Vsupply 511 to all the LED units 570 on the string, and the inductor 562 , FET 561 (which controls the current), and finally through resistor 564 to power supply ground 565. This electrical path from the external power supply Vsupply 511 to the external power supply ground 565 is referred to as a current loop. Note that since there is a branch circuit after the inductor 562, current flows from the external power source through the second voltage source Vclamp 512 to the diode 563. However, since Vclamp 512 is at a higher potential than ground 565, no current flows to Vclamp 512 even when FET 561 is turned on.

  When FET 561 is first turned on, the current increases on the driver circuit as shown in FIG. 5C. However, the increase in current is slowed by the inductor 562 that accommodates the rapid current increase by storing energy in the magnetic field. Therefore, the driver line current ramps upward in the start phase 521 as shown in FIG. 5C. Note that there is a voltage drop through inductor 562 during this time, as indicated by the signs “+” and “−” in FIG. 5A. The LED line driver IC 420 keeps the FET 561 on during this start phase 521 so that the current level of the driver line can be increased to a current that exceeds the desired rated current level 510 by a specified amount.

  When the current through the driver line exceeds the desired rated current level 510 by a specified amount, the LED line driver IC 420 turns off the FET 561 as shown in FIG. 5B so that no current flows through the FET 561 toward the power supply ground 565. To do. However, the inductor 562 counters the sudden change in current flow and instead causes the current to begin to ramp down as shown by the current drop 531 in FIG. 5C. Since current no longer flows through the FET 561 to the ground 565, instead of the slow current flowing through the branch circuit, the current flow when the FET 561 is turned off is shown in FIG. It flows toward Vclamp 512 through 563. This occurs even when the voltage of Vclamp 512 is higher than Vsupply 511. This is because the inductor 562 continues to drive current using energy in the magnetic field.

  The current begins to fall just by turning off the FET 561, but the ramp down that occurs just by turning off the FET 561 is relatively slow. (Because it is slow compared to a ramp where the current rises when FET 561 is on, the rise and fall of the current ramp is asymmetrical.) The ramps where the current falls are accelerated, thereby causing upward and downward currents. To roughly match the lamp, Vclamp 512 is set to a potential higher than Vsupply 511 and a reverse voltage bias is applied to inductor 562 (as indicated by the signs “+” and “−” in FIG. 5B) to Accelerate the ramp down.

  Referring to FIG. 5C, when the current 531 falls below the specified amount and falls below the desired rated current value 510, the LED line driver turns on the FET 561 (returns to the state of FIG. 5A) and is illustrated by the current rise 532. So that the ramp will rise again. The LED line driver IC 420 prevents the driver line current from reaching the final steady state of the direct current. Conversely, the driver circuit repeatedly turns on and off the FET 561 to maintain the driver line current around the desired rated current level 510.

  By turning on / off the FET 561, the LED line driver IC 420 can modulate the amount of current flowing through the driver line in which the rising ramp and the falling ramp are relatively stable. By turning the FET 561 on and off in a manner that correlates the control data, the LED line driver IC 420 can modulate the control data on the driver line in the same manner as the current pattern shown in the data stage 522 of FIG. 5C. Note that if there is not enough data to be sent to the LED line driver IC 420, the LED line driver IC 420 modulates an empty packet on the driver line. In this way, the various LED units on the driver line can maintain synchronization with the data stream modulated by the LED line driver IC 420.

  Referring again to FIG. 4A, the current modulation block 490 receives a data frame from the line data transmission block 450 and modulates it with a driver line like a current ramp pattern. As described above, the current modulation block 490 turns on the external FET 461 (which increases the current by passing the current through the ground 465 of the power supply 410) or decreases the current by applying a reverse bias to the inductor 462. This task can be accomplished by turning off the external FET 461.

  In certain embodiments that use driver line current as a reference current value, current modulation block 490 ensures that the average of the current is desired even if the data on the driver line is modulated by a change in current. It plays a role in ensuring an appropriate rated direct current (DC) level. In this way, the LED unit connected to the driver line can detect the average current level of the driver line and use this current level as the reference current value. In particular, the LED unit connected to the driver line can use the average current level on the driver line as a reference current when generating the current used to drive the LED connected to the LED unit.

  The current modulation block 490 can control the external FET 461 by controlling its internal FET 493. In one embodiment, the internal FET 493 is designed to handle 10 volt fluctuations so that it can control a larger external FET 461 that directly plays a role in controlling the driver line current.

  Modulating data with driver line current is not an easy process. By operating various LED units 470 on the driver line, it becomes difficult for the LED line driver circuit 425 to stably control the current on the driver line. In particular, as shown in FIG. 5A, the various LED units 570 either conduct current to charge the local capacitor (which causes a larger voltage drop across the LED unit) or shunt the line current (which causes the LED unit to Only a small voltage drop occurs), so that the voltage drop between Vsupply 511 and Vline 514 varies depending on the presence or absence of the shunt of the LED unit. As a result, the voltage across inductor 562 varies in the same way, so the rising current ramp (when FET 561 is on) will not always have exactly the same slope. This same phenomenon also occurs in current ramps that fall. In particular, as shown in FIG. 5B, when the voltage applied to the LED unit 570 is changed, the reverse voltage bias applied from the Vclamp 512 to the Vline 514 through the inductor is not always the same, so that the slope of the falling current ramp is changed. To alleviate this phenomenon, it is necessary to limit the various LED units 570 from stopping shunting in time near the edge of the data bit. Nevertheless, shunting or stopping shunting near the edge of the data bit still affects the data modulation / demodulation task.

  Ideally, the current ramp generated by the LED line driver circuit 425 always starts / stops at the rated current value 610, and half of the bit period is completely completed as shown by the ideal current ramp drawn in broken lines in FIG. 6A. It is to be symmetric. However, such ideal current ramp may not always be achieved when the conditions on the driver line change. For example, if a relatively small voltage drop occurs in the LED unit 570 that accumulates on the driver line, a higher voltage is applied by the inductor 562 and the current increases faster than the ideal current ramp (shown by the dashed line) in FIG. 6A. Note that the exact height of the current ramp peak is less important if it is greater than the amount of threshold required for detection.

  To compensate for this, the falling current ramp needs to start at an appropriate time (determined by taking into account the predicted falling slope) and the current level must intersect the rated current level 610 in the middle of the data period. In the example of FIG. 6A, the falling current slope is gentler than the ideal slope, so the descending phase starts earlier than normal and the current ramp peak is shifted slightly to the left. In general, if the absolute value of the slope in the first half of the ramp is greater than the absolute value of the slope in the second half of the ramp, the peak will shift earlier (the time axis in the figure to the left) and in the first half of the ramp If the absolute value of the slope is smaller than the absolute value of the slope in the latter half of the ramp, the peak shifts later (the time axis in the figure to the right).

  To carefully generate the current ramp, the current modulation block 490 of the LED line driver circuit 425 can create a current behavior model to estimate the exact time to change the external FET 461. A variety of different methods can be used to model the current ramp. In one particular implementation, the current modulation block 490 uses an analog computer to model the current ramp to determine when to turn the FET on / off.

  Referring to FIG. 4A, the current modulation block 490 includes two substantially identical analog computer circuits labeled Lamp A491 and Lamp B492. Current modulation block 490 alternately uses the two analog computer circuits, using one analog computer in the first half of the data period and another analog computer in the second half of the data period. Each of the two analog computer circuits uses an analog ramp circuit to estimate when to turn on / off the gate signal of the field effect transistor (FET) 493 (which actually turns on / off the larger external transistor 461). ) Return the end of the current ramp to the rated line current value again at the end of half the bit period. In one embodiment, these analog ramp circuits create a model of how much current changes in the other half of the bit period when the FET 493 is switched instantaneously. In the case of a rising slope, this model clarifies how much current drops from the current amount when the FET 493 is switched instantaneously. This is because a large amount of current may drop when the FET 493 is switched at the start of the half of the bit cycle, or the current may not change at all even if the FET 493 is switched at the end of the half of the bit cycle. is there.

  As described above, the rate at which the current changes depends on the voltage across the inductor 462. In order to calculate the voltage applied to the inductor 462, three different voltage values of Vline 414, Vclamp 412 and Vfetsrc 417 are prepared in the current modulation circuit 490. When the FET 461 is turned on, the voltage applied to the inductor 462 is calculated as a voltage difference from Vline 414 to Vfetsrc 417 (minus a slight drop applied to the FET 461). When the FET 461 is turned off, the voltage across the inductor 462 can be calculated as the voltage difference from Vline 414 to Vclamp 412 (minus a slight drop across the diode 463). These voltage values can be used to estimate the rate of current change (indicated by the slope) and use this rate to determine the exact time to switch the FET 461. Note that these voltage values can actually be read as current through a resistor, but this current is proportional to the voltage by Ohm's law.

  The analog computer circuit (lamp A491 and lamp B492) can be implemented using a lamp circuit and a multiplier circuit. The ramp circuit is used to generate a ramp signal that starts at a fixed full scale value and falls to zero at the end of half the bit period. The ramp signal is then multiplied by an analog multiplier circuit with a voltage difference value that determines the rate of current change (shown as a slope in the graph). At that time, when the FET 493 is turned on, the ramp signal is multiplied by an amount correlated with Vclamp 412 -Vline 414. This is because this amount becomes a voltage applied to the inductor 462 when the FET 493 is turned off. If FET 493 is turned off at that time, the ramp signal is multiplied by an amount correlated with Vfetsrc 417-Vline 414. This is because this amount becomes a voltage applied to the inductor 462 when the FET 493 is turned on again.

  The output of the analog ramp circuit is combined with the value of the current time that the current flows through the driver line (or the estimated time that this current will flow). When the absolute value, which is the difference between the current current and the rated current level, is equal to the amount of current change that occurs as expected by the lamp circuit, the state of the FET 461 changes. The current of the driver line when the FET 461 is turned on can be calculated from the voltage value of Vfetsrc 417. This is because the current of the driver line is equal to the value obtained by dividing the voltage of Vfetsrc 417 by the resistance value of the resistor 464 according to Ohm's law. However, when the FET 461 is turned off, the driver line when the FET 461 is turned off using the line current estimation circuit 495 using the last measured current value and the voltage value applied to the inductor 462 determined by Vline 414 and Vclamp 412. Current can be estimated.

  In order to best illustrate the operation of the lamp circuit, several examples are provided with reference to FIG. 6B. At the start of the data cycle, one of the ramp circuits is charged and multiplied by the voltage difference across the inductor to generate a value corresponding to the amount of current change that occurs when the FET 493 is switched instantaneously. The amount of this current change drops to zero at the end of half the bit period (assuming proper charging). This concept is illustrated in FIG. 6B as lines 651, 652, and 653 depicting various different voltage values across the inductor. Each line starts at the point where the amount of current drop relative to the rated current level 610 is maximum when the FET is switched instantaneously, and drops to zero current at a point 691 at the end of the half bit period. The slopes of the different lines 651, 652, and 653 indicate how fast the current changes based on the voltage across the inductor.

  In order to use the output of the analog computer, the current current value (relative to the rated current level 610) is compared to the current drop expected by the ramp circuit to occur in the other half of the bit period. When the current value intersects the predicted amount of current drop, the FET 493 is switched. In the graph of FIG. 6B, three different examples are shown. In the first example, the current increase 661 is faster than the predicted current drop rate 651, so the system needs to switch the FET 493 before the midpoint 631 and shift the current ramp peak slightly to the left. . Note that the current rise rate and the current drop rate are both affected by the voltage applied to the inductor, and therefore the predicted current drop rate is different for each current rise rate in different examples. In another example, the current increase 663 is slower than the predicted current drop rate 653, so the system needs to switch the FET 493 after the midpoint 631 and shift the current ramp peak slightly to the right. If the current increase rate 662 is substantially equal to the predicted current decrease rate 652, an ideal ramp with the midpoint 631 at the center is formed. However, as long as the peak of the current ramp is within a reasonable distance from the midpoint 631, there will be no problem with the demodulation logic in correctly identifying the current ramp.

  As described above, when the FET 493 is turned off, the current temporarily flows toward the Vclamp 512 as shown in FIG. 5, so that it is difficult to calculate the current flowing through the driver line. Therefore, the technique for calculating the current by measuring the voltage at Vfetsrc 417 in FIG. 4 cannot be used because the current for generating the voltage does not flow through the resistor 464. Alternatively, another ramp circuit, line current estimation circuit 495, can be used to estimate the current in the falling ramp. Thus, referring again to FIG. 6B, the line current estimation circuit 495 can be used to predict the driver line current as shown by the prediction line 680. Note also that the rate of change of current is correlated with the voltage drop across the inductor. Similarly, either of the ramp circuits (491 or 492) is used to predict the amount of current increase in the remaining half of the bit period when the FET 493 is switched instantaneously. When the two prediction circuits output the same absolute value (for the rated line current), the FET 493 is switched.

  The internal logic of current modulation block 490 may be implemented in a variety of different ways. In one embodiment, the system digitally calculates the line current as FET 493 is measuring the voltage at Vfetsrc 417. Then, the digital-to-analog converter (DAC) converts this digital current value into an analog current value, and compares it with the analog current drop prediction value output from the analog ramp generator (491 or 492). If the two values are the same, the system switches FET 493 (which actually turns on / off the larger external transistor 461).

  Referring to FIG. 6C, the entire data period is shown with a rising current ramp followed by a falling current ramp. In the time interval 620, one of the analog lamp circuits (such as lamp A491) is charged to assist in calculating the transition time. At time 621, FET 461 is turned on (if it is not already turned on) to start increasing current and activate charged analog lamp A circuit 491 (how much current drops when the FET is switched off). Display). In time interval 622, the driver line current (calculated from the voltage value of Vfetsrc 417) is compared with the output of analog ramp A circuit 491 to determine how much current drops in the remaining half of the bit period when FET 493 is turned off. Predict. If the two values are substantially equal (within each other's threshold), the current modulation block 490 switches the FET 461 so that the current level can drop again to the rated current value 610 in the time interval 624.

  The time that the system decides to change the state of FET 461 and the time that the effect of this change is detectable by FET 461 must not be equal due to propagation delay. In particular, a delay is seen in the comparison circuit, a delay is seen when the internal driver circuit FET493 is activated, and a delay is seen when the external FET461 is activated. To compensate for these propagation delays, the ramp circuit (491 or 492) may require that the state of the FET be changed shortly before the two values are equal using an adjustment factor. In one embodiment, this can be implemented by setting a constant deviation in the input of the comparator circuit, so that the comparator can be activated early. Thus, the system changes the state of the FET when the two values (current value and predicted current drop value) are within a predetermined threshold of each other. In this way, the FET switches a little earlier than the exact time when the two values (line current and predicted current drop) actually intersect. A closed loop system may be used to calculate an accurate value for adjusting a certain deviation with respect to the comparator.

  In the time interval 624, the current of the driver line again decreases toward the rated current value 610. If the system accurately predicts the behavior of the current, the current level passes the rated current value 610 at the midpoint 625 of the data bit period. In the descending time section 624, the current modulation block 490 charges other analog ramp circuits (such as ramp B492 because ramp A491 was used in the first half of the data cycle), and the amount of current increase when FET 493 is turned on again. Predict. In embodiments that predict driver line current instead of measuring with a falling current ramp, the system also charges a line current estimation circuit 495 that predicts the current level as it falls.

  At the midpoint 625 of the data cycle, the charged analog lamp B circuit 492 and the charged line current estimation circuit 495 are activated. In addition, whether the system has accurately calculated the transition time (in the first half of the bit period) required to sample the current level at the midpoint 625 of the data period and return the current level to the rated current level 610 Can be seen. If there are no current samples available, the final output of the ramp circuit at the midpoint 625 of the data bit period may be examined. If the current level at the midpoint 625 (actual or predicted) is lower than the rated current level 610, adjust the parameters that use the analog lamp A circuit to mitigate the drop (reduce the predicted rate of current drop) Can do. Conversely, if the current level (actual or predicted) at the midpoint 625 is higher than the rated current level 610, parameters using the analog lamp A circuit are adjusted to accelerate the drop (current drop prediction rate Rise).

  In stage 626 of the second half of the data period, the estimated driver line current level is compared with the output of analog ramp B circuit 492 (as estimated using line current estimation circuit 495) and FET 493 is turned on instantaneously. Predict how much current will rise in the other half of the bit period. If this comparison is within a specific threshold at point 627, the FET 493 is turned off and the current level begins to rise. Again, a factor that adjusts the propagation delay (such as a threshold) can be used to request that the FET 493 be turned on shortly before the two values are equal. After turning on FET 493 again, the current level rises during time interval 628 until the end of the data period reaches point 629. In the time interval 628, the current modulation circuit 490 charges another analog lamp circuit (in this example, lamp A491) used in the next data cycle.

  At the end of the data period 629, the current modulation circuit 490 samples the current level to determine if the system has accurately estimated the transition time for the current level to return to the rated current level 610. If the current level at the final point 629 is lower than the rated current level 610, parameters using the analog lamp B circuit are adjusted to accelerate the descent. Conversely, if the current level at the final point 629 is higher than the rated current level 610, the parameter using the analog lamp B circuit is adjusted to reduce the drop.

  In the particular embodiment shown in FIG. 4A, current modulation circuit 490 uses analog ramp circuits (491 and 492) as an analog computer, and the line current when FET 461 switches to estimate when to switch FET 461. The model which predicted the behavior of was made. The analog ramp circuit (491 and 492) is calibrated by a digital system that examines the results after use each time to determine whether the parameters for the analog ramp circuit need to be adjusted, thereby forming a closed loop system Is done.

  However, in various other alternative embodiments, a digital system can be used to predict when to switch the FET 461 to return the current level to the rated current level at the end of half the bit period. In such a system, various related values are sampled using an analog-to-digital converter and then a digital computer system such as a digital signal processor (DSP) is used to determine when to switch the FETs. In such an embodiment, a digital computer system may be used to model the future behavior of the driver line current when the FET 461 is switched. Similarly, digital computer systems can estimate line currents when currents cannot be sampled easily. However, the implementation of such a digital system requires a higher speed analog-to-digital converter, a larger die area for implementing the digital process, and consumes more power than the analog system as previously disclosed. .

  In very different embodiments of the current modulation circuit 490, a current mirror can be used to drive the exact current in the driver line. However, it has been found that such an implementation is less efficient than combining the transistor 461 as disclosed and controlling the inductor 462 that controls the driver line current.

  Referring to FIG. 4A again, the LED line driver IC 420 includes a power supply system circuit block 480. The power supply system circuit block 480 receives a power source from the external power supply 410, generates a necessary power signal using the power, and operates the LED line driver IC 420. In one embodiment, power system circuit block 480 receives power from a relatively high voltage source of about 10 volts, which is used to drive FET 493 with current modulation block 490. The other required voltage levels are generated from the input voltage source and form a voltage source for the other circuits in the LED line driver IC 420. A bandgap reference voltage circuit is used by the power system circuit block 480 to form the various voltage levels. In one embodiment, the high voltage input is used to produce a regulated 5 volt power supply to drive the analog circuit and a 3 volt power supply that powers the digital circuitry in the LED line driver IC 420.

  In one embodiment, the 3 volt power supply and / or the 5 volt power supply obtained from the power supply system circuit block 480 is capable of producing extra current, so the 3 volt power supply and / or the 5 volt power supply is Can be used to power small external devices. For example, a 3 volt power supply and / or a 5 volt power supply obtained from the power supply system circuit block 480 can be used to power a small master LED controller system such as a microcontroller device connected to the LED line driver circuit 425. .

  The LED line driver IC 420 can implement a ground fault interrupter (GFCI) system for safety and legal compliance. In particular, the power supply system 480 of the LED line driver IC 420 can receive information from the external power supply 410 about how much current is sent toward the downstream of the driver line starting from the point of VSupply 411. Alternatively, the LED line driver IC 420 can detect this current in several known ways according to the prior art, such as using a current sensor. This amount of source current can then be compared to the amount of current at the end of the driver line (output current). For example, the amount of current reaching the end of the driver line can be detected by measuring the voltage at the point Vfetsrc 417. (Note that some current flows also towards the position of VClamp 412, so the current flowing through this location also needs to be taken into account.) If the source current is significantly different from the output current, some current will be driver There is a case where the earth is leaked to a ground other than the ground 465 of the power supply 410 which is the end of the line. If there is a leaking current at locations other than points Vfetsrc 417 and VClamp 412, several potential malfunctions may occur. In response to this, the LED line driver IC 420 can turn off the system and stop the current drive downstream of the driver line. In some embodiments, the LED line driver IC 420 can stop for a period of time and then resume operation after some time to determine if the problem was misdiagnosed or just a transient problem. When a transient or serious problem is detected, the LED line driver IC 420 sends error and diagnostic information to the controller system using the data output 431.

Second Embodiment of LED Line Driver Circuit Using Dip Mode As mentioned above, there are a variety of different methods that can be used to modulate data on the driver line. FIG. 4B shows a second embodiment for the LED line driver circuit 425, which uses different types of current modulation blocks 490 along with various external circuits for modulating data with current. In particular, the current modulation block 490 and its external circuitry implement a “dip mode” modulation system that modulates data at the rated current using the current dip as shown in the timing diagram of FIG. 3C. To do.

  Referring to FIG. 4B, the LED line driver circuit 425 uses two external field effect transistors (FETs) (481 and 482) and a double winding inductor 483. The current modulation block 490 uses the first FET 481 to maintain the rated current of the driver line loop configured with a standard forward converter using the primary winding of the inductor 483. Current modulation block 490 uses the second FET 482 to drive the secondary winding of inductor 483 so that the second FET 482 can quickly drop the loop current to zero. This current drop is referred to as a “current dip” and the current modulation block 490 uses such a current dip to modulate data on the line. The current modulation block 490 includes a loop current sensing circuit 496 that monitors the driver line current by measuring the voltage just before the resistor 464 towards ground 465.

  In one embodiment, the current modulation block 490 modulates the data on the driver line by modulating the current drop timing. In this way, the LED unit connected to the driver line detects the current drop and demodulates the data by calculating the relative timing of the various current drops. For example, in the timing diagram of FIG. 3C, the line driver circuit generates a current dip at ¼ of the data bit time interval to modulate the data bit of “0” and 3/4 of the data bit time interval. At that time, a current dip is generated to modulate the data bit of “1”.

  Rather than using a single double-winding inductor, two different inductors may be implemented in the system. A first inductor can be used to maintain the driver line current. In order to generate a current drop using the second current drop driver circuit FET482, a second inductor can be used. In such an embodiment, a resistor in the source terminal of the FET towards ground is used to turn off the FET 481 that functions as a sustain current when the loop current reaches an appropriate value, and the second FET 482 sets one bit. The loop current can be sensed by turning the FET 481 back on when it is modulated and the current drops below an appropriate value.

Adjustable current based on energy requirements In the system of the present disclosure, the current used to drive circuitry on the unit connected to the driver line is decoupled from the current driven by the driver line. In particular, each unit connected to the driver line generates its own local energy storage in the capacitor and operates using this local energy storage. Therefore, it is possible to generate a local current (such as a current used for driving the LED) that is much larger than the current of the driver line in each unit. However, the total power average used by all individual nodes on the driver line does not exceed the average total that the line driver circuit supplies to the driver line. Therefore, the peak power used by individual units may temporarily exceed the power available on the driver line due to the use of local capacitors that serve as energy storage.

If the accumulated power used by all the individual units connected to the driver line is significantly lower than the amount of power available in the driver line current, some of the power obtained from the driver line current is wasted. In particular, power proportional to I ² R is wasted by various resistance elements on the driver line, such as shunts to individual units and wiring of the driver line itself. Here, I is the current of the driver line, and R is the cumulative resistance value of the resistance elements on the driver line.

  To prevent this unnecessary energy loss, when it is known that each node on the driver line requires less power, the line driver can instead reduce the amount of current on the driver line. For example, if the individual units on the driver line are LED units used to produce outdoor digital LED signs, these individual LED units require significantly less power at night. At night, the human pupil spreads so that more light enters the eye, so less energy is needed to make the sign visible. Therefore, if the digital LED sign is activated at night, much less power is required to activate the sign. This improves sign visibility and saves energy.

The advantage of this fact is that the LED line driver can supply enough power to operate all the individual LED units even if the amount of rated current is reduced to a low level. With adequate current, the individual LED units on the line still drive their local LEDs, but use a reduced duty cycle to reduce the brightness of the LEDs. When the duty cycle is shortened, less power is required, and therefore less power is drawn from each driver unit from the driver line. Therefore, the line driver can reduce the rated current level on the driver line. Since the power loss caused by the accompanying resistance is proportional to the square of the current (I ² R power loss), the amount of energy can be greatly reduced by reducing the rated current.

  It should be noted that the master control system recognizes when it is appropriate to reduce the current level output by the line driver, since the master control system provides data to control the brightness of the LEDs. . Thus, the master control system determines when the various line drivers should lower (and increase) the rated current level.

  FIG. 6D shows a timing diagram of the current signal produced by the line driver, showing how the required energy is reduced from the daytime operation mode to the nighttime operation mode. The line driver is slowly reducing the rated current level 610. This data is continuously modulated around the rated current level. As long as each individual LED unit on the line can track where the rated current level is, each LED unit can adjust itself to a gradually changing rated current level 610.

AC Current Line Driver While the main embodiment disclosed herein describes an embodiment that is powered primarily by direct current (DC), it is also possible to create an alternating current (AC) embodiment. is there. The direct current embodiment has the advantage that the integrated circuit is originally operated using direct current. However, the unit connected to the AC line may be provided with additional circuitry that creates a local direct current that powers the integrated circuit on the unit.

  There are several different ways to create a system that operates on alternating current. The first method is to supply power to two different strings from the AC line driver unit. A diode in the line driver is used to operate with a positive pulse on one string and operate with a negative pulse on the other string.

  In another embodiment, diodes are used in individual line units so that each line unit operates with a half-wave rectifier. Using local diodes, individual line unit chips can be configured to target only current in one direction. Half of the individual units can be configured to target positive pulse currents and the other half of the individual units can be configured to target negative pulse currents. In a more costly embodiment, each line unit connected to the driver line may be provided with a full wave rectification system to maximize the current.

  A variety of different systems can be used to modulate the data on the driver line with the AC current. In a modulation system, phase, frequency, duty cycle, or run length encoding can be used. Several advantages are achieved by driving the current loop with an alternating current AC. For example, because alternating current allows transformer coupling, a loop voltage higher than that produced by readily available semiconductors is obtained at each unit on the driver line.

Individually Controlled LED Units As described in the previous section and illustrated in FIG. 2A, the LED line driver circuit 220 connects to one or more individually controllable LED units (250-1 to 250-N). The modulated current source is driven on the driver line 221. The only means of electrical contact to the LED unit 250 is through a single driver line 221. Therefore, the LED unit 250 must receive all the resources that the LED unit 250 requires for operation from this single driver line 221. In order to realize this, the driver line 221 performs a plurality of functions for the LED unit 250. Each LED unit (250-1 to 250-N) draws the required operating power from the current on the driver line 221. Each LED unit also demodulates the LED control data modulated by the LED line driver circuit 220 with this current. In one embodiment, each LED unit 250 also uses the rated current level driven by a single driver line 221 as a reference current value. In this section, the interior of the LED unit 250 will be described in more detail.

  FIG. 7 is a block diagram showing an embodiment of an LED unit 750 that can be individually controlled. In the particular embodiment shown in FIG. 7, the LED unit 750 is comprised of an LED controller 760, four light emitting diodes (LEDs) 781, and a power supply capacitor 729. The power capacitor 729 acquires, stores, and supplies operating power to the LED unit 750. The LED controller 760 may be an integrated circuit that provides most of the functionality of the LED unit 750.

  The LED unit 750 is connected to a string driven by an upstream LED line driver circuit (such as the LED line driver circuit 425 shown in FIG. 4A) via an input 721 to the driver line. In particular, the input 721 to the driver line provides a modulated current source to the power system 720 on the LED controller 760. The operation of the power supply system 720 will be described with reference to FIG.

  When the LED unit line is operating in normal operating mode, there is very little LED unit that tries to draw charging power from the driver line at the same time, so the cumulative drop incurred for all the LED units connected to this line Will not be so big. For example, if there are 48 LED units in a certain driver line, and each LED unit takes 4 volts during charging but only tries to charge 1/4 of the LED unit at a specific time, the power supply is 48 units in total. It is only necessary to supply 4 volts / unit x 1/4, or 48 volts. However, when the line driver first starts operation, the line driver needs to activate all the LED units on the driver line. Initially, all LED units on the same driver line will attempt to charge simultaneously to begin operation. If the voltage available from the power supply at the start is only 48 volts, each LED unit will be charged to about 1 volt (48 volts / 48 LED unit) and will become inoperable. Therefore, once the entire system is initialized, a specific amount of power supply voltage may be sufficient to operate the LED unit line, but this same power supply voltage activates all LED units connected to the driver line. May have problems.

  To solve this potential problem, each power supply system on the LED controller chip has an analog bootstrap power supply circuit that allows the LED controller to reach the specified extreme low voltage limit. A current is passed through the chip and the power system at start-up switches off as the voltage increases. Thus, when the LED controller 760 is activated with reduced power, the analog bootstrap power supply system operates first as described in step 805. The analog bootstrap power supply system checks to see if the current exceeds a specified low voltage threshold (approximately 1.3 volts in one embodiment) while stepping current while increasing current. When the analog bootstrap power system reaches a specified voltage threshold, the analog bootstrap power system is turned off and the main power system 720 is activated. The main power supply system 720 begins to take charge from the driver line and charges the local power supply capacitor 729 at step 810.

  By charging local power supply capacitor 729 in this manner, the voltage drop across LED controller 760 from driver line input 721 to driver line output 722 increases. When the voltage drop applied to the LED controller 760 increases, the voltage to the other LED controllers on the same line decreases, so that the other LED controllers do not reach the threshold value for starting charging. When the LED controller completes charging, the LED controller power system 720 shunts current directly from the driver line input 721 to the driver line output 722 and operates with local power from the local power capacitor 729, thus the LED controller 760. The voltage drop across is significantly reduced. This allows other LED controllers on the same line to receive the increased voltage, so that any of the other LED controllers exceeds the threshold voltage and starts charging.

  In order for this activation system to function properly, the average voltage of the LED controller chip needs to be lowered once the LED controller chip is fully charged. Therefore, the operating current of the LED controller chip divided by the threshold for switching off and multiplied by the current must be smaller than the current that activates the loop. To meet this requirement, the line driver on the string will determine that all the LED units on the loop have been fully activated and send very little current until a command is sent and normal operation is possible. Design LED controller chip. In one embodiment, the LED controller chip has a starting threshold voltage of 1.3 volts for 15 milliamps and an initial operating current of 2.4 milliamps for 3.5 volts. Since 2.4 × (3.5 / 1.3) is less than 15 milliamperes, the startup condition is satisfied. Therefore, in order to ensure that all LED units connected to the line start up normally, the line driver only has to produce a voltage of a number that is 1.3 volts multiplied by the number of LED controller chips on the line. Good.

  Referring again to FIG. 8, after the LED controller exceeds the threshold voltage, the power supply system 720 charges the external power supply capacitor 729 in step 810, and in step 815 the power supply system 720 connects the external power supply capacitor 729 to the LED controller 760 (power supply system). Charging continues until it is determined that there is sufficient power to operate the logic circuit within (including 720). The external power supply capacitor 729 substantially acts as a small battery and supplies power to the LED controller 760 in the LED unit 750. The power supply system 720 periodically stops the shunting to take in current from the driver line 721 and recharges the power supply capacitor 729 according to power requirements.

  When enough power to start operation is stored in the external capacitor 729, the circuit in the LED controller 760 enters the start-up mode at step 820 and only a subset of the circuits are active. For example, LED driver circuit 780 is not yet active. During the start-up mode, the control circuit in the LED controller 760 performs a series of start-up actions, with which the LED controller 760 configures itself based on the state of the non-volatile fuse in the fuse block 741. The LED controller 760 then waits for a command to start normal operation at step 825. In this step 825, the LED controller activates any LED, takes a small amount of power to charge other LED units in the same driver line, and enters the activation mode without producing a high cumulative voltage on the driver line. Basically, during this wait state 825, the LED controller only tracks the driver line data stream and follows the command, and may occasionally draw power for continued operation.

  After the line driver determines that the entire loop is activated, the line driver sends various commands for configuring the LED unit to the LED unit so that the LED unit can start normal operation. Commands sent to configure the LED unit include commands for fine-tuning current, calibration, brightness scaling, addressing, and driver circuit routing as described in later sections. Upon receipt of the appropriate command, the LED controller 760 enters a normal operation mode at step 840.

  During normal operation 840, the power supply system 720 monitors the charge state of the power supply capacitor, switches from line shunting to capacitor charging if necessary, and the external capacitor 729 has enough charge to operate the LED controller 760. Make sure it can be used. In particular, when power is required, the shunt is turned off and charge is stored in the external capacitor 729. When it appears that the capacitor is full, the power supply system 720 stops charging and shunts the line current, causing only a small voltage drop, and the current flowing into the driver line input 721 causes the power supply system 720 to Through to the driver line output 722. The current emanating from the driver line output 722 then drives the granular LED unit, and eventually wraps around the LED line driver circuit, terminating the circuit.

  In addition to holding the charge required for operation in the capacitor, the power supply system 720 can also be used to carefully monitor the power required by the LED controller 760 in step 845, so the amount of charge stored in the capacitor can be adjusted as needed. Can be adjusted. For example, when the LED controller 760 first turns on the blue LED, the power required for the LED controller 760 increases, so the system proceeds to step 850 to indicate the additional power required to drive the blue LED. If the LED controller 760 then turns off the blue LED and turns on the lower power red, the LED controller 760 proceeds to step 860 to indicate that less power may be required to drive the LED. can do. In this way, the LED controller 760 uses power in a very efficient manner to maintain only the minimum voltage required for operation of the LED unit 750 in the external capacitor 729.

  When there are a large number of LED units 750 in a single driver line, the accumulated voltage of the plurality of LED units 750 connected in series may increase because each LED unit 750 attempts to charge a local capacitor. In the worst case, each LED unit 750 in the driver line tries to take charge at the same time, so the accumulated voltage drop on the line will cause the voltage drop across each LED unit when charging to be the LED unit on the line. Multiply by number. In a driver line with a large number of LED units, this cumulative voltage drop may be a problem due to legal restrictions and power supply restrictions.

  To prevent the worst situation, the driver line current can be increased and multiple LED units 750 on the same driver line can be commanded to conduct charge in a regulated manner. For example, only a limited number of LED units 750 may be able to stop shunting to charge the local power supply capacitor simultaneously. By increasing the amount of current on the line, each LED unit 750 on the line can charge the power supply capacitor at a faster rate. By increasing the line current and limiting the number of units that can carry current simultaneously, the overall voltage of the line can be maintained within a specified range.

  One way to adjust the shunt of the various LED units 750 is on a bit-by-bit basis. Each data bit in the data frame can be assigned a number starting with zero and ending with N-1, where N is the number of bits in the data frame. Thereafter, each LED unit 750 can only be commanded to stop shunting every X bits, where X is the number selected by the LED line driver circuit. For example, if the number 4 is selected for X, the first group of LED units 750 stops shunting only when the number of bits is 0 modulo 4 (bits are 0, 4, 8, etc.). The second group of LED units 750 stops shunting only when the number of bits is 1 modulo 4 (bits are 1, 5, 9, etc.). The third group of LED units 750 stops shunting only when the number of bits is 2 modulo 4 (bits are 2, 6, 10, etc.). The fourth group of LED units 750 stops shunting only when the number of bits is 3 modulo 4 (bits are 3, 7, 11, etc.). By adjusting the shunt stop on a bit-by-bit basis (as opposed to a long time interval), each LED unit 750 needs to wait a long time until the LED unit is given time to capture more charge from the driver line. Disappears.

  The power supply system 720 may include an analog circuit section that is capable of generating a bandgap reference voltage and setting the voltage adjusted to an amount just right to turn on all the local LEDs as described above. The power system 720 monitors the wrong LED output (short circuit or open circuit) and attempts to adjust the voltage to the lowest voltage level required to operate with the LED turned on. All changes related to the operation of shunting the line current and the operation of stopping the shunt are performed in coordination with the data on the line, so that the LED chips all transition simultaneously. This adjustment is done to minimize potential data errors.

  The analog section of the power system 720 includes a bandgap reference that is used as a reference voltage for three of the four main power related functions of the power system. First, the bandgap reference is used to generate a voltage source (about 2.8-3.2 volts) for the core digital circuit. Second, the bandgap reference is a reference to a digitally controlled voltage divider circuit that samples the power supply of the LED driver circuit and compares it to the bandgap reference. Finally, the bandgap reference voltage can be used with an overvoltage / excess current detector. The overvoltage detector uses carefully matched poly resistors to detect excess voltage at the power source of the LED driver circuit and to measure line current. The overvoltage detector is activated whenever capacitor 729 is charging. If there is a capacitor whose overvoltage condition is detected due to insufficient dimensions, the chip will transition immediately to protect the chip.

  The fourth function of the power supply system 720 is the line shunting performed by the line shunt and line current rectifier section, which shunts the line current to the driver line output 722 or power supply capacitor 729. Set digitally to charge. In normal operation, the power supply system 720 periodically stops the shunting of the line current so that the current is in a direction to recharge the power supply capacitor 729. This shunting may be performed in a manner that coordinates with other LED units connected to the same driver line so that multiple LED units do not attempt to capture current from the driver line simultaneously.

  It is an extremely important function for the LED controller 760 that the power supply system 720 stops the shunting of the driver line 721 and charges the power supply capacitor 729. This is because charging of the power supply capacitor is necessary to obtain power necessary for the operation of the LED controller 760. Similarly, it is very important to stop the shunting of the driver line 721 after charging the power supply capacitor. This is because if the power supply system 720 cannot quickly shunt current through the output driver line 722 when the power supply capacitor 729 is fully charged, the LED controller 760 will correctly operate with an overvoltage that destroys the integrated circuit of the LED controller 760. May not function. Therefore, shunting and shunting of the input driver line 721 are tasks that require careful control by the power supply system 720.

  Fortunately, this situation, which requires careful balancing, is a very serious situation where a malfunction of an LED controller on a driver line in series with another LED controller does not significantly affect other LED controllers in the same driver line. Provides a convenient way. In particular, a circuit in the LED controller 760 that has malfunctioned becomes malfunctioning, and the power supply system 720 stops charging the external power supply capacitor 729, but instead becomes permanently shunted. 720 acts as a short circuit through which line current flows (generally with a slight voltage drop across the shunt). Therefore, other individual LED controllers in the same driver line continue to receive current from the line driver circuit.

  On the other hand, the circuit in the malfunctioning LED controller 760 is different from the above, that is, the power supply system 720 is stagnant in a state of shunting and continuously charges the external power supply capacitor (and the current is supplied to the external power supply In the event of a malfunction, such as a shunt condition towards the capacitor), the power system 720 acts as an open circuit, affecting all LED controllers in the same driver line. However, until the integrated circuit (similar to a zener diode or perhaps just a short circuit) is eventually broken by the voltage across the power system 720, the total current flowing through the LED controller 760 causes the voltage across the power system 720 of the LED controller 760 to To increase. Once such damage occurs, driver line current flows again from the driver line input 721 through the malfunctioning LED controller 760 and out to the driver line output 722. By passing the current through the malfunctioning LED controller 760, other LED controllers in the same driver line (721 and 722) can continue to operate normally. In order to add protection, a withstand voltage device (such as a Zener diode or an equivalent device) that requires a voltage higher than that normally indicated by the LED controller 760 can be placed in parallel with the LED controller 760. In this way, even if the LED controller 760 malfunctions in an open circuit manner, the voltage increases until it reaches a higher voltage required for the operation of the withstand voltage device, thereby causing an electrical path around the malfunctioning LED controller 760. Can do.

  In order to prevent damage to the LED controller 760, the temperature of the integrated circuit of the LED controller 760 can be monitored with a temperature system. When the temperature exceeds the danger threshold, the power system 720 enters a shutdown state to prevent damage to the LED controller 760. In one embodiment, the power supply system 720 may be in a state where the power supply system 720 permanently enters a shunt state and the current flowing to the driver line input 721 flows directly to the driver line output 722. In this way, other LED units in the same driver line can continue to operate normally. If a particular LED controller 760 is repeatedly in such a shutdown state, this LED controller 760 may need to be replaced. In other embodiments, the LED controller 760 is in a reduced functionality state where only some of the electrons continue to operate, and in this state it is rare to stop the shunting to secure extra power. . In this way, the LED controller 760 periodically conducts a temperature test, and when the temperature falls, it activates itself again.

  Two functions independent of the power that the power supply system 720 can provide are the generation of a reference current value and the generation of a current copy for data acquisition. In order to drive an LED with the most stable light output characteristics, a certain amount of current must flow through the LED. When the luminance of an LED is controlled by changing the amount of current flowing through the LED, the spectrum of the color emitted by the LED changes depending on the amount of current flowing through the LED. Since the ideal goal is to have a constant color spectrum, the current modulation technique does not provide the desired performance. In addition, since LED brightness is not linearly related to current intensity, it is difficult to accurately control LED brightness using current fluctuations.

  Instead of using current intensity to control the brightness of individual LEDs, the brightness of the LEDs is controlled by controlling in a typical manner that regularly turns on and off a constant current duty cycle. A known system that implements this technique of controlling power is commonly known as “pulse width modulation”. This is because the luminance of the LED is proportional to the pulse width of the constant current intensity in a predetermined time interval. In one embodiment, the system of the present disclosure uses different techniques and modulates both the number of constant current pulses in a given time interval and the width of these constant current pulses to obtain the desired brightness. This alternative system is termed “Reduce Flicker Modulation” (RFM) and is described in detail in a later section, including the LED driver circuit 780.

  In order to optimize the output performance of the LED, the amount of current used to drive the LED 781 with each constant current pulse needs to be as stable as possible. Therefore, a stable reference current value is necessary. Various different methods can be used to generate the reference current value. The present specification provides two different systems that cause the power supply system 720 to generate a reference current value.

  In the first method for causing the power supply system 720 to generate a stable reference current value, a reference voltage value is used. In particular, a stable reference current value can be generated by generating a stable reference voltage value using a bandgap circuit and then flowing the stable reference voltage through a resistor. Next, when the reference current value is supplied to the LED driver circuit 780, the driver circuit generates a constant current using the reference current, and drives the LED 781 in a stable manner using the constant current.

  In an alternative embodiment, the power supply system 720 may generate the reference current by sampling the driver line current. In particular, the power supply system 720 samples the driver line current and calculates an average current value of the driver line flowing from the driver line 721 (rated line current as shown in FIG. 3A). Next, the average value of the line current is used as a reference current value for the LED driver circuit 780. The average driver line current is updated / calculated only while the power supply system 720 shunts the driver line.

  Another function independent of power performed by the power system 720 is the generation of a line current copy for data acquisition. In order to be able to recover the data modulated by the line current of the driver line 721, the power supply system 720 extracts a reduced copy of either the current shunt sensing result or the current shunt stop sensing result (or diode). Supply to block 730. The current shunt sensing result is supplied when the power supply system 720 is in shunt mode, and the current shunt stop sensing result (or diode) is the power supply system 720 charging the external power capacitor 729. Sometimes supplied.

  The clocking / data extraction block 730 receives a copy of the driver line current from the power supply system 720 and the data modulated by the LED line driver circuit 425 of FIG. 4A with the driver line current (LED controller configuration commands and current LED control data). Etc.). In order to demodulate the data sent from the driver line current, the data extraction block 730 must first generate its own internal clock signal and then use its digital phase locked loop circuit (DPLL) to generate its own internal clock signal. Are synchronized with the data rate of the data modulated by the driver line current, and finally, the internal clock signal and the current ramp modulated by the driver line current are appropriately arranged to acquire data.

  To generate an internal clock signal, the digital subsection of clocking / data extraction block 730 implements a high speed ring oscillator and has associated digital logic that operates at a high ring oscillator rate. This high-speed oscillator rate digital logic subsection provides several functions that can only be provided with a higher clock rate. The first function is that the high speed clock section provides digital support to ensure that the centering logic located in the middle of the current ramp is exactly in the middle of the line current data stream. The second function is to divide the high-speed free-running ring oscillator clock by the counter count N. When dividing by the counter count N, only the core clock boundary is updated to help prevent glitches. The value divided by the counter N from the high speed clock section is useful for implementing a DPLL circuit that tracks the data modulated on the driver line 721. The data rate of the data stream on the driver line obtained using the digital phase-locked loop circuit is used to generate the core clock signal used to drive most LED controllers 760. In one embodiment, the core clock rate operates at 8 times the driver line data rate (8 ×).

  In one embodiment, the clock logic circuit initially sets a fixed value for division by the counter count N and counts shunts by level crossing with an A / D converter to provide an initial estimate of the data clock frequency value. Generate. The clock logic then loads this initially estimated frequency value into the digital phase locked loop circuit, which attempts to track the driver line data rate. If the clock logic does not obtain tracking confirmation from the digital phase-locked loop circuit within a certain time, it enters a resynchronization mode where the clock logic restarts the clock frequency measurement process.

  The main part of the clocking / data extraction block 730 operates at the core clock rate generated using a digital phase-locked loop circuit. Most of the main parts of the clocking / data extraction block 730 comprise the circuitry used to implement this digital phase-locked loop circuit (with assistance from the fast clock section).

  In addition to the digital phase-locked loop circuit, the main portion of the clocking / data extraction block 730 includes data extraction logic that extracts the actual data from the driver line signal. The data extraction logic serves to distinguish the transition between the data center and the data edge. This is because the digital phase-locked loop circuit may track the transition of the data bit edge rather than the center of the data bit. In particular, referring to FIG. 9A, the appropriate data bit time 921 ramp mode signal is almost the same as the wrong data bit time 922 signal where the DPLL tracks the transition of the data bit edge rather than the center of the data bit. appear. To avoid this problem, the data extraction logic looks for a signal whose signal before the center of the data bit is different from the signal after the center. This is because correct data bits always appear in this way. In particular, the wrong data bit time 925 indicates how the signals at the front 931 and the back 932 of the wrong data center (actual data bit edge) look the same. This informs the data extraction logic that the digital phase-locked loop circuit has tracked the transition of the data bit edge rather than the center of the data bit. If the front and back values are often too the same, the data extraction logic moves the array of ½ of the bit period to accurately align with the center of the data bits.

  FIG. 9B illustrates the same problem seen with a dip mode modulated signal. Referring to FIG. 9B, the dip mode signal at the appropriate data bit time 971 looks almost the same as the dip mode signal at the wrong data bit time 972. The centering circuit ensures that the first half and the second half of the data bit period are different in order to prevent the wrong tracking of the data bit period. Therefore, if the bit time interval does not include a dip as shown in time interval 975, or if the bit time interval includes two dips as shown in time interval 976, the centering logic circuit is incorrect. Judged that the time interval was tracked.

  Referring again to FIG. 7, after accurately tracking the data rate and aligning correctly with the center of the data bits, the clocking / data extraction block 730 forwards the demodulated data stream to the data processing core 740. The data processing core 740 is a block of a digital logic circuit that processes received LED control data. In one embodiment, the data processing core 740 identifies individual data frames, parses the data frames to obtain LED controller configuration commands, LED control commands, and LED parameter data, and then obtains them from the LED control data. It plays the role of executing the command.

  In one embodiment, the first action performed by the data processing core 740 on the received LED control data is descrambling the data stream. The data stream decoded by driver line 721 may be scrambled for a variety of different reasons.

  One reason for scrambling is to prevent the LED unit 750 from tracking the wrong data framing signal. If the value of the LED control data transmitted redundantly to a particular LED unit 750 happens to be the same as the value of the framing sync header, then the LED controller will track the wrong location in the data stream and provide valid data There is a risk of not paying attention to the frame. This situation is prevented by scrambling the data. This is because even if the payload of the data is a fixed value, each data frame becomes different on the driver line by scrambling the data. Therefore, scrambling the data greatly reduces the possibility of generating an incorrect framing pattern in the data stream. Another reason for scrambling the data is to mitigate the problem of electromagnetic interference by scrambling the data and dissipating energy. In order to process the scrambled data stream, a descrambling unit 742 in the data processing core 740 first processes the received data by looking for a frame synchronization marker, and then descrambles the data frame in the data frame. Get the actual data command.

  In one particular embodiment, the LED control data frame consists of 40 bytes as shown in FIG. 2B. The following table shows the structure of the data frame shown as an example in FIG. 2B.

  In the table above, the first byte is the frame header used to indicate the start of the data frame. The frame header bytes are not scrambled and the remaining 39 bytes are v. 34 self-synchronizing scramblers can be used to scramble. The data frame detection logic of descrambling unit 742 retrieves input data for repeating frame headers in the data stream. The descrambling unit 742 attempts to track such a pattern. If a data frame is found after some time, descrambling unit 742 informs clocking / data extraction block 730 of the problem. The clocking / data extraction block 730 switches to the new frequency and exercises the synchronization signal again. This action resets the frame lock that could have been initiated and activates the claim detection logic of the descrambling unit 742 that retrieves the data frame again.

  When the frame detection logic of descrambling unit 742 detects the data frame pattern, descrambling unit 742 returns a valid frame signal to clocking / data extraction block 730 to indicate valid data. In one embodiment, the descrambling unit 742 has activated at least one frame and the data parser block 743 has obtained valid data and the descrambling unit 742 has tracked the incoming data stream and the correct output. Make sure you have the data. This ensures that the descrambling unit 742 is synchronized with the incoming data stream. When the descrambling unit 742 accurately tracks the input data and completes the descrambling process, the descrambling unit 742 sends the descrambled data frame to the data parser 743 to process the contents of the data frame. Forward.

  The data parser 743 parses the data frame. The data parser 743 identifies the command (LED controller configuration command or LED control command) in the data frame and decodes the payload (LED controller configuration parameter or LED control data parameter) of the data frame. In one embodiment, the data parser 743 optionally performs a cyclic redundancy code (CRC) check, and if the data is correct, the data parser 743 forwards the decoded command and parameter data to execution logic in the data processing core 740. To do.

  In one embodiment, the data parser 743 has a plurality of different pixel addressing modes that are used to determine whether a particular received data frame should be applied to this particular LED controller 760. In the address field of the data frame, the standard addressing mode sets the address of a specific LED unit. In one embodiment, this address specifies the starting address for the LED control data in the data field. The particular LED unit identified in the address field uses the first item of LED control data in the payload field until the width of the LED control data is reached. The next LED unit subsequently addressed uses the next item of LED control data in the payload field until the width of the LED control data is reached, and so on. In other embodiments, the address may specify a single LED unit or a specific number of consecutive LED units. Note that since the size of the data payload is 288 bits in this system, it is possible to store multiple data values that are 2, 4, 6, 8, or 12 bits wide.

  In the group address mode, the LED control data in the data payload is applied only to LED units assigned to a specific group. The control data is simply applicable to all LED units in the group. In one embodiment, the system uses a bitmap processing engine that examines the bitmap in the payload to determine which portions of the group's LED unit members have changed and these LED unit members are You can determine how it changes. As such, each LED can be individually addressed with a standard linear addressing system, and each LED can be individually addressed as part of an assigned group.

  Data errors detected by cyclic redundancy code (CRC) checks can be handled in a variety of different ways. In one embodiment, if protection with optional CRC is possible, the data processing core 740 starts ignoring data if two errors are detected by the CRC while processing approximately 25 data frames. Further, during this time, the LED output can be turned off and the data processing core 740 will not respond to new commands. In one embodiment, the data processing core 740 continues to examine incoming LED control data frames until it receives four data frames with the correct CRC value. At this point, the data processing core 740 starts processing a new command.

  A wide variety of commands can be implemented in the LED controller 760. In one particular embodiment, three main types of commands are implemented. These commands are a command for updating pixel data without performing a global update, a command for updating pixel data by performing a global update, and a command for writing to a control register in the LED controller 760. In pixel update without global update, a series of parameters for driving one or more LEDs is stored in the shadow register. However, these LED parameters are not used immediately. Thus, when a global update command is received (for this LED controller 760 or any other LED controller), the stored pixel data parameters are used to change the output of the LED driver circuit 780. In this way, multiple pixel changes can be synchronized as required by video displays and other display systems in which different display frames operate sequentially.

  When data processing core 740 receives a command to write to a control register, data processing core 740 identifies the appropriate control register in control register / fuse block 741 and writes the associated data value to this control register. The contents of the control register are volatile control bits that control the operation of the circuitry within the LED controller 760. Several patterns can be written to the control register to trigger various functions instead of simply setting the value of the specified control register.

  In addition to the volatile control register, the control register / fuse block 741 also includes a series of non-volatile fuses. The fuse can be blown to specify a series of permanent configuration information in the LED controller 760. For example, in one embodiment of LED unit 750, an 8-bit address value is implemented using eight fuses. In this way, a string of 256 LED units that can be uniquely addressed can be connected to a single LED line driver circuit. In order to program the fuse in the control register / fuse block 741, a specific write pattern is transmitted to the address of the designated control register. (Note that such a specific control register address may or may not be an actual control register.) When a correct write pattern is sent to the specified control register address. The data processing core 740 blows the specific fuse identified by the control register / fuse block 741.

  The fuse in the control register / fuse block 741 can be used by both the manufacturer of the LED controller 760 and the user of the LED controller 760. Manufacturers can use the fuses in the control register / fuse block 741 to create a wide variety of different LED controllers with different performance characteristics and features from the same integrated circuit design. For example, the fuses in the control register / fuse block 741 may include the number of LEDs that the LED controller 760 controls, the accuracy of the LED control (4 bits, 6 bits, 8 bits, or 12 bits in one embodiment), and various others. Can be used to specify features of some LED controllers that may or may not be possible. In this way, the manufacturer of the LED controller 760 can segment the market for the LED controller 760 according to how many features are required for a particular application.

  The fuse in the control register / fuse block 741 can also be used to store calibration information in the LED controller 760. Due to incomplete and unstable semiconductor processing techniques, the behavior of two integrated circuits will not be exactly the same. In purely digital integrated circuits, minor differences do not affect operation because digital circuits use separate quantized data values. (If the manufacturing of a digital integrated circuit device is significantly incomplete, an inoperable device is born and discarded.) In the case of the LED controller 760, if there are a large number of analog circuits, manufacturing differences may vary. This will significantly affect the behavior of.

  To deal with such behavioral differences, each individual LED controller 760 is inspected and stores calibration data that adjusts for various differences seen between different LED controllers and minor differences between different LED controllers. This can be compensated by using a fuse. For example, the brightness of the LED is controlled by the amount of current flowing through the LED. However, since the manufacture of integrated circuits is not perfect, the amount of current supplied by the LED driver circuits 780 of different LED controllers when commanded to provide the exact same brightness level is not the same. Therefore, the current fine adjustment value designed to calibrate the current that the LED driver circuit 780 flows to the LED can be stored using the fuse in the control register / fuse block 741. Each different LED channel in the LED controller 760 can individually receive a unique current fine adjustment value.

  Note that the LEDs themselves are also adversely affected by imperfect manufacturing techniques. Even if different LEDs receive the same amount of current, they do not output the same brightness. Therefore, by connecting the LED 781 to the LED controller 760 before testing, slight manufacturing differences in both the LED controller 760 and the LED 781 can be programmed into the LED controller 760 by calibrating the calibration data with fine current adjustment. Can be compensated. This ability to calibrate the current output provided by the LED driver circuit 780 allows the LED controller 760 to use less expensive LEDs that have not passed strict brightness calibration tests. This is because, in addition to the changing LED driver circuit 780, the changing LED is also compensated by the value for calibrating the current.

  The user of the LED controller 760 can program a series of fuses accessible to the user for a variety of different uses of the specific features available to the user. For example, the LED controller 760 can be designed to operate either a common anode LED or a common cathode LED. The use of a CRC value to test the data frame because an error has occurred can be specified by a fuse. Also, as previously described, the user can also program a series of device address fuses.

  In rare cases, a blown fuse may appear to be unblown when the various elements in the integrated circuit move due to heat or other factors. When this happens, the fuse programming performed on the LED controller 760 becomes impossible and the device may not operate normally. To prevent this phenomenon from occurring, one embodiment includes an extra fuse that may be blown to perform an error correction coding (ECC) scheme. Therefore, if the fuse is not blown, it is possible to determine which fuse has not changed using the ECC and adjust the operation of the LED controller 760 accordingly.

  As previously described, in some embodiments of the disclosed system, the LED unit responds to the status request with the requested information to allow the LED line driver to request status from the LED unit. Similarly, in some embodiments, the LED unit provides authorization after receiving a command. To respond to (or approve) the status request, the data processing core 740 can request the power supply system 720 to operate the shunt circuit in a manner that is detectable by the LED line driver circuit in a specified time frame. . To determine which LED unit 750 is responding, the LED line driver circuit can provide only one request at a time or provide each LED unit 750 with a different time frame to respond within that time. Another signal transmission method using a shunt circuit is a method in which the power line system transmits a high-frequency burst signal of an operation of stopping the shunting and an operation of shunting so that the LED line driver circuit can detect the frequency. .

  Referring to FIG. 7 again, the final circuit block of the LED controller 760 is a circuit block including an LED driver circuit 780 that drives the LED 781. The LED controller 760 has an LED driver circuit independent for each LED output. In the embodiment of FIG. 7, there are four different LED driver circuits that drive four different LEDs 781. However, other embodiments include an LED driver circuit that processes a different number of LEDs 781. In the particular embodiment shown in FIG. 7, the LEDs 781 are wired in a cathode common configuration. In the anode common configuration, the LED symbol points in another direction.

  Each independent LED driver circuit includes both a digital circuit portion and an analog circuit portion. The digital circuit portion is coupled to the data processing core 740 and the control register / fuse 741. The digital circuit portion receives digital information that specifies an intensity value that indicates how much power the LED should receive. This intensity value is then adjusted according to various factors and used to drive a constant power output. The analog LED driver circuit receives a reference current from the power supply system 729, generates a constant current, and uses this constant current to actually drive the associated device.

  The digital part of the LED driver circuit precisely controls when the associated LED is turned on / off. To determine how to drive the LED correctly, the digital portion queries the control register / fuse 741 for configuration information. The control register / fuse 741 may operate the LED, whether the LED is reducing current or supplying current (using the anode common mode or cathode common mode shown in FIG. 7), LED Some current fine-tuning values for can be specified, and several different parameters can be specified, such as LED lighting delay factors. This LED configuration information is combined with the LED control information received in the LED control data frame that specifies the LED intensity value (zero to turn off the LED) and determines how to drive the LED. A variety of different power modulation systems can be used to drive the LEDs.

  In addition to the current fine adjustment value fixed as specified by the fuse, the LED driver circuit 780 can also significantly adjust the current flowing through the LED. For example, the output of the temperature detection circuit may be supplied to the LED driver circuit 780. Then, the LED driver circuit 780 can adjust the current supplied to the LED in response to room temperature. In this way, the LED driver circuit 780 can adjust for temperature differences that can affect LED performance and the LED driver circuit itself. It should be noted here that by providing an internal temperature sensor for each LED unit, the disclosed system allows accurate pixel-by-pixel correction. Therefore, when some of the LED units are exposed to the sun and the remaining LED units are not exposed to the sun (for example, due to the shadow), the individual LED units make correct corrections based on their local conditions.

  In conventional pulse width modulation (PWM) embodiments, the output power is determined by the pulse width output during a predetermined time interval. For example, in FIG. 10A, the time of 16 time units is defined, and it is defined how the 4-bit intensity value is expressed by the pulse width modulated power in this time interval. If the intensity is zero (“0000”), there is no pulse. If the intensity value is 1 (“0001”), a pulse having a width of one time period is output. If the intensity value is 2 (“0010”), a pulse having a width of two time zones is output. In this way, the process continues until the intensity 15 ("1111") is output for 15 times of time period pulses. The conventional pulse width modulation described with reference to FIG. 10A can be used in the LED driver circuit 780 in the LED controller of the present disclosure. However, a new output method called “reduced flicker modulation” (RFM) may be used which has several advantages.

  Flicker mitigation modulation systems have at least three advantages over conventional pulse width modulation systems. In particular, the flicker mitigation modulation system (1) increases the frequency of switching (switch on and off) to a higher frequency range, thus reducing the sensed flicker and (2) using current over time. Because of the spread, the demand for peak power is reduced, and (3) randomization is introduced to prevent various patterns depending on the data from affecting the output in a prominent manner. Spreading current utilization is important in systems with limited available power. For example, if the average available current (buffered by a capacitor) is only 140 milliamps and there are two LEDs operating at a constant current of 100 milliamps, each set operating at a 60% duty cycle, then average There is enough current. However, if a PWM system is used to drive the LEDs, both LEDs will operate for at least 10% of the time, and during this time two LEDs will flow together for 200 milliamps, so they can be used on average More current flows than current. In an RFM system, the current utilization spreads evenly over time, so on average no more current will flow through the two LEDs than is available, thus avoiding overloading the current supply from the line Is done.

  To increase switching frequency and spread current usage more evenly, the flicker mitigation modulation system provides constant current output to substantially the same number of time units for a given time as a PWM system, The time unit when is turned on is distributed equally over the time interval. FIG. 10B shows how flicker mitigation modulation outputs a constant current pulse for the same energy output as the PWM example shown in FIG. 10A.

  To generate the output pattern of FIG. 10B, the four patterns of FIG. 10C associated with each bit position can be ORed if each bit position of the intensity value is on. For example, specifying intensity level 9 (“1001”), the pattern associated with the most significant bit position (“1000”) and the pattern associated with the least significant bit position (“0001”) are shown in FIG. 10C. Both can be logically ORed together.

  Comparing the output of the pulse width modulation system of FIG. 10A with the output of the flicker mitigation modulation system of FIG. 10B, more individual pulses are generated for each time interval when power is output by the flicker mitigation modulation system. In particular, the pulse width modulation system of FIG. 10A has only one constant current pulse per time interval, whereas a flicker mitigation modulation system that spreads energy more evenly over the time interval has multiple constant current pulses. There is. Each of the constant current pulses generated by either system does not completely form an ideal square pulse. FIG. 10D is an enlarged view of an ideal current pulse drawn by a broken line and a more realistic current pulse drawn by a thick solid line. As shown in FIG. 10D, the rising time and falling time of the constant current pulse do not become zero as shown by the ideal square pulse. In an actual constant current pulse, the rise time is generally longer than the fall time. (In this specification, such a rise time is called “LED turn-on delay”.) Therefore, the amount of energy output during an actual constant current pulse is an ideal square constant current. Less than the amount of energy output during the pulse. Therefore, this reduced energy output causes the LED output to be smaller than the desired output. If this effect is not compensated, the output scale of the intensity will not be linear.

  In order to compensate for this effect, the digital circuit of the LED driver circuit 780 counts the number of constant current pulses to be generated, and after adding a plurality of constant current pulses, an extra constant current pulse time unit is added. For example, if an actual constant current pulse of a single time unit outputs 5% less energy than an ideal square constant current of a single time unit, an extra constant current time unit is added for every 20 pulses generated. . This is because 20 × 5% = 100%, that is, pulses of the entire time unit are lost. In one embodiment, an adjustable LED lighting delay value stores a value representing the amount of energy lost in each pulse. The LED turn-on delay value is added to the associated LED accumulator after each constant current pulse. If the accumulator becomes overcapacity, an extra time unit is added during the time the LED is “on” to supplement this lost energy.

  As described in the description of the clocking / data extraction block 730, the LED controller 760 uses a free-running internal ring oscillator to generate a core clock signal that is used to drive the circuit. A fast free-running ring oscillator clock can have several clock jitters. In order to generate the core clock, the high-speed free-running ring oscillator clock is reduced by division by the counter count N controlled by the digital phase-locked loop circuit. Using a digital phase locked loop circuit to generate the core data clock introduces some quantization error in the core clock. As a result, the internal core clock has a slightly different length of time for each core clock period. Since the core clock is used to drive the output of the LED, the time unit when the LED is on is thus slightly different in length of time.

  If this slight inaccuracy that occurs in clocking when the LED is on overlaps with the pattern of LED control data where the clocking is in the incorrect phase, the effect of the LED will be significantly affected due to the synergistic effect. There is a risk of receiving. In order to prevent this slight imperfection of clocking from combining the LED on / off data pattern with a negative effect on the LED output performance, the LED on / off data pattern Introduce randomization of output on / off. In particular, the time for turning on the LED can be moved randomly within the time interval. However, since the LEDs remain lit for the same amount of time during the time interval, the net LED power output does not change. For example, FIG. 10E shows three possible different examples of randomization of the output pattern of FIG. 10C. In one embodiment, this randomization adds to the LED on / off control pattern using a linear feedback shift register (LFSR) that generates a pseudo-random bit stream. This randomization introduced in the LED on / off output pattern effectively eliminates the possibility of data subordinate to the pattern interacting with incomplete clocking and negatively impacts the intensity of the LED. To do.

  In addition to the above two constant current methods (pulse width modulation and flicker mitigation modulation) for controlling the LED intensity, other means may be used to drive the LED 781. For example, the brightness 781 of the LED can be controlled using a method of changing the current intensity supplied to the LED. However, this method should be avoided because good and stable color output cannot be obtained.

  The digital circuit portion uses the analog portion of the LED driver circuit 780 to drive the associated LED. The analog LED driver circuit uses the reference current received from the power supply system 720 and drives the LED with a constant current pulse. The analog LED driver circuit sends a signal to the power supply system 720 when the voltage is not sufficient from the power supply system 720 for the analog LED driver circuit to operate normally. The analog LED driver circuit also signals the power supply system 720 when the LED appears to have malfunctioned. In particular, if the current through the LED is too high or zero, the LED driver circuit can determine that the LED appears to be a short circuit or an open circuit, respectively. When an LED malfunctions, the system stops activating that LED. The system periodically re-examines the LEDs to determine if a malfunction has been incorrectly detected or if the problem is transient. When the system determines that one LED has malfunctioned, the LED controller puts many other LEDs associated with the malfunctioning LED into a stopped state. For example, if a single LED set of red, green and blue LEDs used to generate a color pixel fails, all three LEDs associated with this pixel may be deactivated.

  In one embodiment, the LED driver circuit monitors the current supplied to the LED and makes calibration adjustments based on the current flowing through the LED. For example, if there are multiple LEDs of the same type but more current flows through some LEDs than other LEDs, the LED driver circuit may adjust the rate of constant current pulses supplied to the LEDs accordingly. it can. For example, the current pulse rate can be set high for the LED that receives less current, and the power output of different LEDs can be made equal.

  A technique for adjusting the rate of the current pulse with respect to the detected current difference can be used regardless of whether the current difference is intentional or unintentional. The current difference can be intentionally generated to improve energy efficiency. In particular, by consuming excess voltage as heat, the system supplies the same voltage to different LEDs instead of carefully adjusting the voltage supplied to the different LEDs and applying the same amount of current to each LED. be able to. However, since there is a manufacturing error between different LEDs, a different amount of current may flow through each LED. To equalize the current difference, various rates of current pulses corresponding to this difference can be supplied to each LED. Low current LEDs receive high rate current pulses. Therefore, instead of equalizing the current in a way that consumes excess energy inefficiently, different LEDs are equalized by adjusting the rate of the current pulses supplied to each LED.

  The LED line driver circuit 425 of FIG. 4A connected to the complete LED unit 750 of FIG. 7 forms a highly efficient LED lighting system that minimizes the amount of wasted power. In the LED line driver circuit 425, the main line driver FET 461 is always completely on or completely off, so that very little power is dissipated as heat. In an individual LED unit 750, all current flows to the next LED unit on the line because the local power system 720 shunts the line current when charging the local power capacitor of the LED unit. Inside the individual LED unit 750, the control circuit uses minimal power, so the LED driver circuit 780 distributes most of the power to the LEDs 781 that are turned on. Therefore, the LED lighting system that is controlled as a whole is extremely efficient. The system draws only a limited amount of power when the LED is off. Also, when the LED is on, the system consumes little power.

  As shown in the embodiment of FIG. 7, each LED unit controls four different LEDs, but other embodiments may have a different number of LEDs. To further optimize power usage (and reduce costs), each group of three LED units controlling N LEDs is used, each supporting one color (each red, N pixels can be implemented by having green and blue LEDs). For example, in the embodiment of FIG. 7, four independent pixels can be generated by having each LED unit control four LEDs of the same color. This deployment of the LED unit further optimizes the power usage. This is because different color LEDs require different amounts of power, and each LED unit only carries the power necessary to support a particular color LED (red, green or blue).

Advanced Color System In an alternative embodiment, individual LED units can be implemented as pixel circuits with color data for driving color pixels, where the LED units consist of red, green and blue LEDs. Each LED unit can control one or more pixels. The pixel circuit receives color / luminance information for each pixel controlled by the pixel circuit. The pixel circuit can operate using the following scheme for encoding a number of different colors.
Color space of YUV or YCrCb or YPbPr RGB (Red (Red), Green (Green), and Blue (Blue)) color space HSV (Hue (Hue), Saturation (Saturation), and Value (Lightness))) Space CMYK (Cyan (Cyan), Magenta (Magenta), Yellow (Yellow), and Black (Black)) color space

  The pixel circuit converts the received color information into values necessary to drive a set of red, green and blue pixels to generate a desired color. In order to produce very sharp colors, the individual pixel circuits can take into account the current supplied to the LED and the current temperature. The pixel circuit adjusts the output intensity value for each color LED, which depends on the current temperature and the current supplied to the LED.

  Display systems that perform color space conversion at the pixel level provide several advantages. The system for supplying display information can be simplified because the system for supplying image data does not need to perform color space conversion. Instead, this color space conversion is performed where the pixel light is generated.

  Furthermore, a system that supplies all color information to the pixel light source can directly use the original color space, and therefore can provide a higher quality output. For example, since the RGB color space has a lot of mutual overlap, the YCbCr color space is more efficient than the RGB color space. Furthermore, there are no quantization errors that occur during the color conversion process. Therefore, by providing color information encoded with YCbCr to a system that renders pixel light, a system (pixel circuit) that renders pixel light uses all of the color information to produce the most vivid color. A reproduction can be generated.

  As previously described, the system is energy efficient by providing a voltage source that is not carefully calibrated to obtain the exact desired voltage, but instead supplies approximately the desired current instead. Can be improved. In such a system, the emission spectrum of the LED may be affected. As described above, in the pixel circuit that performs color control, the color circuit can adjust the color output with respect to the current supplied to the LED. Therefore, when the current supplied to the LED changes the color output of the LED, the color control circuit can account for this change in color output and adjust the output of all LEDs for this pixel, Finally, an accurate color output can be generated. In this way, the current actually supplied to the various different color LEDs used to generate the color pixels is the input to the color circuit that determines the exact output intensity for each color LED.

Automatic addressing system As mentioned above, if all individual LED controller units in a single driver line can be individually controlled, each LED controller unit (760 in FIG. 7) is assigned a unique address. There is a need to. This connects the LED line driver circuit to a single individual LED controller unit on the driver line, sends a command from the LED line driver circuit to this single LED controller unit, and sets its address fuse to a specific address. This can be achieved by fusing against the value. After that, a series of LED controller units, each having a unique address, are connected together in series on a single driver line in a specific pattern, and a driver line with individually controlled LED controller units arranged in a known arrangement. Can be made.

  To facilitate the creation of such a string of LED controller units, the address programming logic can be improved by adding a “Hall Effect” sensor. A Hall effect sensor is an electrical sensor that can detect a local magnetic field. To improve the address programming logic, the Hall effect sensor may be added in such a way that the address programming logic can be activated only when the Hall effect sensor detects a particular magnetic field. Thus, the address programming logic does not operate when the LED controller unit is not in a predetermined magnetic field. In this way, several LED controller units that have not yet been addressed by blowing a fuse can be connected to the same driver line. Next, in order to give a unique address to the LED controller unit on the driver line, each LED controller unit is sequentially placed in an appropriate magnetic field (one at a time), and a command for programming the unique address is given to the driver line. Send downstream. Since there is only one LED controller unit in an appropriate magnetic field, only this one LED controller unit responds to an addressing command by blown fuse. Other LED controllers in the same driver line ignore the address assignment command due to fuse blow. Therefore, by placing each LED controller unit in the appropriate magnetic field in sequence and sending a command to program with a unique address, each LED controller unit already connected together in a single driver line has its own address. Can be programmed.

Application Overview The single-wire multiple LED power and control system described in the above section and shown in FIG. 2A can be used in a wide variety of applications. In the most basic application, a string of individually controlled lighting units 250 can be placed in a simple controlled decorative lighting system, such as a series of lights for a Christmas tree. In such an embodiment, the driver line 221 is an insulated wire, in addition to transmitting power, supplying encoded control data, supplying a reference current value, and serving as a heat sink for the individual LED units 250. The string can be given a physical structure. In such an arrangement, the master LED controller system 230 may be a small microcontroller with a variety of different illumination patterns. These illumination patterns have no limiting elements other than the imagination of the person programming the master LED microcontroller system 230. Examples include: fixed illumination with a spectrum of colors, illumination patterns that flash in various colors, progressively actuating LED units to make the light source appear to move through the string, etc.

  The number of possible applications for the single-wire multiple LED power and control system described in the above section is almost endless, and that number is beyond the scope of this document. However, the following sections list some of the many possible uses for the disclosed system.

Controlled Lighting Applications As described in the background art herein, LEDs are currently used in many traditional lighting systems. Two main reasons for this are that the LED is energy efficient and that the LED is robust and requires little maintenance of the LED lighting system. (LEDs do not need to be replaced as often as filament-based incandescent bulbs or small fluorescent lamps.) However, because of the high cost of LED-based lighting systems, their placement is limited. The single-wire multiple LED power and control system according to the present disclosure reduces the cost of LED-based lighting systems while improving the set of features of LED-based lighting systems. As such, a single-wire multiple LED power and control system according to the present disclosure can expand the market for LED-based lighting systems.

  The single-wire multiple LED power and control system of the present disclosure reduces the complexity of the lines involved in designing, manufacturing and installing LED-based lighting systems, and reduces the cost of LED-based lighting systems. Reduced. In particular, a single driver line (and a return supply line to complete the circuit) greatly simplifies the lines needed to build an LED-based lighting system. As shown in FIG. 2A, in one possible embodiment, the functions of the master LED controller system 230, power supply 210, and LED line driver circuit 220 are incorporated into a single LED driver circuit system 239, Only the driver line 221 (and its return line 229) drives a number of individually controlled LED units (250-1 to 250-N). In this way, the manufacture of the lighting system is greatly simplified. However, since the LED lighting system of FIG. 2A will control all the LED units 250 (each having a plurality of LEDs of different colors) individually, a highly multicolored pattern can be generated.

  11A-12 are block diagrams of possible LED lighting systems that may be constructed using the teachings of this disclosure. Note that these are only two examples of the myriad of possible lighting fixtures that can be generated using the teachings of this disclosure.

  In the embodiment of FIG. 11A, the LED lighting system was divided into two units. LED lighting equipment 1125 and master LED controller / power line data encoder system 1130. The embodiment of FIG. 11A can be used in a conventional alternating current (AC) lighting environment. A part of the LED lighting equipment 1125 is installed like a conventional lighting equipment that is usually controlled by switching to an AC current. However, instead of the conventional lighting switch, the master LED controller / power line data encoder system 1130 is installed at the place where the on / off switch is normally installed.

  The master LED controller / power line data encoder system 1130 includes a power supply, a microcontroller, a user interface, and a power line data encoder. The user interacts with the user interface in the master LED controller / power line data encoder system 1130 to supply control commands (turn on, turn off, set light to blue, display rainbow pattern, etc.). The microcontroller / power line data encoder then modulates the control command on the power line connecting the master LED controller / power line data encoder system 1130 to the LED lighting equipment 1125. A variety of different known power line data modulation systems can be used.

  In a possible embodiment shown in FIG. 11A, the user interface in the master LED controller and power line data encoder system 1130 may comprise a pair of pointer boards. Using the first brightness pointer panel 1135, it is possible to control whether the LED lighting equipment is turned on and how much brightness the LED should be lit. When the second hue pointer board 1136 is used, a specific hue can be selected for the LED unit. If the hue pointer board 1136 is set to white, the LED lighting equipment 1125 can operate as a normal white light source.

  The master LED controller / power line data encoder system 1130 drives an LED lighting facility 1125 that can be installed like a conventional lighting facility. A power supply and data extractor 1110 in the LED lighting equipment 1125 receives, modulates and extracts control commands from the control and power line 1131. The power supply and data extractor 1110 then transfers the extracted control data and required power to the LED line driver circuit 1110 to drive the series of LED units 1150 as described in the previous section of this specification.

  A single master LED controller / power line data encoder system 1130 can drive multiple LED lighting fixtures. For example, in the embodiment shown in FIG. 11B, a single master LED controller and power line data encoder system 1130 can be configured with three LED lighting fixtures (just like conventional lighting switches to control multiple overhead lighting fixtures ( 1125, 1126, and 1127).

  FIG. 12 illustrates an alternative embodiment of a lighting system controlled by a wireless control system. In particular, FIG. 12 shows an alternative embodiment of a lighting system that includes an LED lighting fixture 1229 and a wireless LED control transmitter 1238. The LED lighting equipment 1229 may be installed at the same place as the lighting equipment using the conventional AC current. The AC power 1211 sent to the power supply 1210 in the LED lighting equipment 1229 generates the necessary DC power for the LED line driver circuit 1220 and the master LED controller system 1230. (Note that in one embodiment, the master LED controller system 1230 can receive operating power from the LED line driver circuit 1220.)

  The master LED controller system 1230 includes a sensor circuit 1232 that receives wireless commands from the LED control transmitter 1238. Master LED controller system 1230 decodes the command received from LED control transmitter 1238 and forwards the command to LED line driver circuit 1220. The wireless system may use Bluetooth®, infrared light, or other suitable wireless data transfer system. When using an infrared transfer system, the function of the LED control transmitter 1238 is operated by a programmable infrared remote control system. Therefore, the LED lighting equipment 1229 in FIG. 12 is ideal for use in a room equipped with a home theater system. The AC power 1211 for supplying power to the LED lighting equipment 1229 is obtained from a lighting switch provided on a conventional wall. In accordance with general expectations, the master LED controller system 1230 always turns on the LED lighting equipment with a default mode of white light. In this way, the LED lighting fixture 1229 operates like a normal lighting fixture when the LED control transmitter 1238 is not in use.

Use of LED string technology for stage lighting systems Special concert lighting systems are used for music concerts and performances to improve the performance of live performances. There is a specialized industry dedicated to the development and sales of lighting hardware and control systems for stage lighting. In order to allow mutual exchange of information between various devices, the American Theater Technology Association (USITT) has developed a standard communication protocol known as DMX512-A that is used to control stage lighting and effects. The DMX512-A communication protocol is a serial protocol based on EIA-485 for transmitting commands for stage lighting and effects units.

  For beneficial use in the stage lighting market, the teachings of the present invention can be implemented in conjunction with the general DMX512-A communication protocol. In the first embodiment, the DMX512-A communication protocol for the LED line driver unit can be converted into a native protocol using the conversion unit. For example, referring to FIG. 2A, the master LED controller system 230 can be a microcontroller unit (MCU), which receives commands at the DMX512-A communication protocol or input 232 and translates these commands. After that, these commands are output to the control data 231, and this control data is transmitted to the LED line driver unit 220 by the native protocol. The LED line driver unit 220 then drives the individually controlled LED units 250 as described in the previous section of this specification. The master LED controller system 230 relays the DMX512-A communication protocol information to the next DMX512-A based device in the daisy chain configuration.

  The teachings of the present disclosure can also be used in a dedicated DMX512-A based system. FIG. 13 shows a system implementation of a line driver circuit 1320 dedicated to a DMX512-A based stage lighting system 1339. Using a conventional DMX512-A based controller system 1330, data 1331 in the DMX512-A format is transmitted to the DMX512-A based line driver circuit 1320. The current sent to the power supply 1310 can be transmitted through the same line. The DMX 512-A data interface 1325 in the line driver circuit 1320 receives and decodes a command in the DMX 512-A protocol format.

  Next, the line driver circuit 1320 converts these commands, and transmits the converted commands to the downstream of the driver line 1321 along with the current supplied to the individually controlled LED unit 1350. The individually controlled LED unit 1350 receives this command and executes it appropriately. Note that the individually controlled LED unit 1350 can not only light the LEDs at various brightness levels, but also perform other additional functions. For example, the individually controlled LED unit 1350 may additionally incorporate features such as LED pan and tilt and the use of gobos. (A gobo is a filter or pattern used on the front of a light source to give an effect on light output.)

  The DMX 512-A data interface 1325 can output the DMX 512-A protocol so that the DMX 512-A based unit 1327 next to the string in the daisy chain configuration also receives control data. Similarly, a power signal can be sent from the power supply 1310 to the next DMX512-A based unit 1327.

Use of LED strings in automotive applications Many different light sources are used in automobiles. For example, in the case of a typical automobile, at least four turn indicator lamps, two brake lamps, an interior lamp, a license plate lamp, a brake lamp mounted in the center, a trunk light, a bonnet light, a reverse indicator lamp, and the like in the corner of the automobile There are other lamps. Different types of bulbs can be used for each such different lamp, depending on the specific brightness and color needs. In order to drive such various different lamps, various different sized harnesses are stretched around the automobile. Since there are various types and configurations of cars, a wide variety of line harnesses are required. This conventional system creates a difficult inventory management problem because a large number of different line harnesses and light bulbs must be stocked.

  To simplify automotive wiring, a single-wire string of multiple LED units as described in the previous section can be used in an automotive environment. A single wire can be stretched around the car, and all the outputs of the various different lamps mounted on the car can be connected (with room for each lamp's output). For example, start a single wiring from the control position, then forward left indicator light, forward right indicator light, interior light, rear right indicator light, rear right brake light, rear left indicator light, rear left Brake lamps, reverse indicator lamps, license plate lamps, trunk / hatch lamps, and other required lamp positions, and finally can be wired back to the central control position. Next, this wiring is cut at each place where a light source is required, and the LED lamp unit 250 to be controlled is connected continuously to this wiring.

  Control of all lamp units in the string is handled by a central control unit (such as LED drive system 239). Since the central control unit precisely controls how light is output from each lamp unit (color, brightness, and their changes), the same lamp output unit can be used at all different locations. For example, the central control unit reliably flashes the turn signal indicator lamp in yellow, outputs the brake lamp in red, and outputs the reverse indicator lamp in white. To improve safety, two independent strings are operated in parallel, and even if one string malfunctions, the other strings continue to operate. Even two systems operating in parallel, such as a two-wire system, are far simpler than the myriad wirings used in conventional automotive electrical harnesses.

  Since the lighting system of the present disclosure is fully controllable, the central control unit mounted on the vehicle can be used in a different manner than is normally used for vehicle lighting. For example, if a car is stolen, a wireless communication system (such as a mobile phone network or an OnStar network provided by General Motors) instructs the lighting system to start lighting all the lamps of the vehicle in an annoyingly conspicuous pattern, A stolen car can be eye-catching. The same technology can be used to make it easier for people to find a car in a large parking lot. Lamps installed in cars can also be used to output information in various ways. For example, a car external lamp train can be used to output the state of charge (or other data) of the battery in the form of a bar graph. The output of the controlled lamp can also be used to output the encoded information to various sensors installed along the road. For example, a sensor for detecting various identification patterns can be installed in a parking lot or a toll booth to recognize a specific car for use of the service or charge the car.

  In addition to simplifying automotive design and inventory management of automotive parts, the LED string system of the present disclosure is extremely energy efficient. As cars eventually move from gasoline to electricity, the efficiency of all the electrical systems in the car becomes critical. As such, the LED-based lighting system of the present disclosure would be ideal for use inside an electric vehicle. The system not only uses an energy efficient LED as a light source, but can also carefully control the amount of light as needed. For example, the brake lamp needs to output a large amount of light during the day to be visible, but can be adjusted to reduce the output at night (thus saving energy).

  In addition to automotive applications, LED string systems are also ideal for use inside aircraft. While weight is key in aircraft, lightweight LED string systems can provide the least weight of lighting. In addition, the lighting is controlled so that the same lighting can be used for multiple purposes such as normal white light, mood light and emergency exit light.

Use of LED Strings in Modular Display Systems A display system can be made using a single wire, multiple LED power and control system as described in the previous section. In particular, referring to FIG. 2A, the individually controlled LED units 250 can be arranged in a two-dimensional pattern so that the individually controlled LED units 250 can be controlled as individual pixels in the display system.

  FIG. 14 illustrates a system that uses a single LED line driver circuit 1420 to drive 64 individually controlled LED units (1450-1 to 1450-64) arranged in an 8 × 8 two-dimensional array. An example is shown. A 16 × 16 array can be created with 256 individually controlled LED units on a single driver line. (Note that this is only an example, modules of different sizes and shapes can be made, and such modules may be combined with any desired pattern.) A single power supply 1410 is an LED. Power is supplied to the entire array of line driver circuits 1420 and individually controlled LED units (1450-1 to 1450-64). One of the most important aspects of the two-dimensional array system shown in FIG. 14 is that all individually controlled LED units (1450-1 to 1450-64) are connected to the driver line 1421 using only a single wiring. That is. This makes it extremely easy to construct the array system of FIG.

  The LED line driver 1420 is controlled by a master LED controller system 1430 that transmits pixel control data 1432 to the LED line driver 1420. In addition to controlling the LED line driver 1420, the master LED controller system 1430 controls many other LED line drivers that each also drive its own 8x8 array. Larger display systems can be combined by modularly combining multiple arrays. For example, FIG. 15 illustrates the concept of a 10 × 8 array of even smaller two-dimensional module arrays. If the 8 × 8 array of FIG. 14 is used in the configuration of FIG. 15, the overall display is 80 × 64 pixels. Higher resolution displays can be made using more individually controlled LED units in each module unit and / or more units.

  In addition to a two-dimensional display system, the disclosed LED string can be configured into a three-dimensional pattern. With a three-dimensional LED string, a three-dimensional image can be generated.

Use of LED Strings in String Display Systems The single wire multiple LED power and control system described in the previous section can be used to create a variety of different display systems that are not conventional. For example, several long strings of individually controlled LED units can be mounted in parallel with each other to create a two-dimensional display system as shown in FIG. At the beginning of each string, the line driver unit drives a single line to control all individually controlled LED units on the string. All line driver circuits can be controlled by a single master controller system that sends the appropriate data and renders the image on the array. The display system of FIG. 16 can be easily rolled, carried or installed anywhere that requires a large display system. In another embodiment, individually controlled LED units can be attached to a flexible sheet such as a conventional roll-up reflective projection screen. This is because flat and flexible wiring can be used to connect individually controlled LED units. Such a display system can be rolled up, carried and installed like a carpet wherever a large display system is needed.

  If a plurality of strings of individually controlled LED units are combined and arranged, virtually any surface can be created in the display system (the surface is not necessary when hanging the strings). There is no need to do so in a careful manner to place a plurality of strings of individually controlled LED units. Once several types of two-dimensional patterns are created, the calibration system can be used to identify the two-dimensional pattern and calibrate the pattern. An example is given with reference to FIGS.

  Referring to FIG. 17, the creation of a free form display system begins with placing several strings of individually controlled LED units at step 1710. The strings are arranged in any way that produces at least some two-dimensional patterns when viewed from an advantage different from LED strings. For example, in the case of a building, a plurality of different LED strings can be attached to one side of the building. A plurality of two-dimensional arrays may be generated and controlled. For example, a track can be covered with a plurality of LED strings so that the two main sides of the track function as a two-dimensional array.

  Next, at step 1720, all LED strings are connected to a single master LED control system, such as a computer system. The master LED control system obtains information regarding the number of LED strings attached and the number of LED strings provided with addressing information, which allows the master LED control system to address each LED unit independently. At this point, it should be noted that the master LED control system has no information about the positional relationship of the arranged LED strings.

  Next, at step 1730, the calibration camera system is placed at a point on the display system that is convenient for viewing. In the example of an LED string that attaches to the side of a building, a suitable and advantageous point would be a sidewalk across the street from the building. In the truck example, an appropriate and advantageous point might be 6 meters (20 feet) from the side of the truck. (Note that two different calibrations are performed on both sides of the track.) After installing the calibration camera system, the master LED control system displays a series of calibration patterns at step 1740. The calibration pattern is used to specify the position and relative brightness of each LED unit of various LED strings. By this calibration, a two-dimensional pattern of the arranged LED units can be identified. LED units that are not visible to the calibration camera are ignored (for example, the view is blocked in the example of the LED unit on the other side of the track).

  This calibration system appears to require a connection between the master controller system and the calibration system to facilitate the correlation between the displayed current calibration pattern and the image captured by the calibration system. . However, an encoding system that transmits the address of each LED unit by color output, flicker pattern, or a combination of the two can also be used to match the calibration screen with the captured calibration image.

  After capturing the calibration patterns and using these patterns to identify the relative position and brightness of each LED unit, the calibration information is stored in the master LED control system at step 1750. At this point, the master LED control system has information about the positional relationships of all visible LED units used to create a two-dimensional array model. The master LED control system can render the image by sending an appropriate message to the LED unit after converting the image using this model. The master LED control system can distribute a portion of the calibration operation to the individual LED units by sending a portion of the calibration information to the individual LED units as described in optional step 1760. For example, a particular LED unit cannot be directed to an advantageous point in the calibration camera system with a brightness that appears to be lower than other LED units. To compensate for this, the calibration data in this particular LED unit can be specified to increase the brightness of this LED unit.

  Once the LED string is placed, the calibration information is captured, and a two-dimensional array model is created, the free-form display system is ready to operate at step 1770. However, when manufacturing two or more two-dimensional arrays using LED strings, two or more display systems may be defined. For example, for a track covered with an LED string, a second display system can be made by selecting a second advantageous point on the opposite side of the track. Thus, in step 1765, the user can choose to repeat steps 1730-1760 for another two-dimensional surface (ie, the opposite side of the track) and create another display system model from the same set of LED strings. To do.

  FIG. 18 shows how a series of LED strings arranged with a display model made using the method of FIG. 17 can be used to display video information. The display system uses this model to convert the video information into LED control commands that are sent to the individual LED units.

  Viewed from the left of FIG. 18, any type of suitable video source, such as computer system 1810, DVD 1811, HDMI 1812, Blu-ray 1813 or other video source, is provided to frame decoder 1820. Frame decoder 1820 decodes the original video source into a series of digital frame representations. Below the frame decoder 1820 is the concept of a video frame.

  Next, the frame counter 1830 adjusts the scale of the original source frame to a size that fits the display. For example, the resolution of the original video frame may need to be reduced or increased using interpolation methods. Frame counter 1830 may reduce the amount of video information that needs to access and process only a portion of the original video frame. Below the frame counter 1830 is a conceptual representation of a video frame reduced in size from the original video frame below the frame decoder 1820.

  Next, in step 1840, remapping of the positional relationship of the source video is performed. Free-form display systems do not appear to be a suitable two-dimensional array that accurately corresponds to conventional rectangular video frames. Thus, image clipping, frame distortion, and pixel interpolation can be performed to match the video source frame to a free form display system. Below the positional remapping step 1840 is an image concept that distorts the frame to compensate that the freeform display is not rectangular.

  Finally, the data distribution system 1850 scans the modified source frame, generates a series of LED unit commands, and sends them to LED units appropriately addressed according to the display model. Underneath the data distribution system 1850 are various display string model concepts that create a free-form display system. The data distribution system 1850 sends LED update commands to the various LED string controllers (1880-1 to 1880-N). By repeating the steps 1820-1850 for the original source video frame, a series of LED strings (with individually controlled LED units) and a model of the LED strings arranged as produced by the method of FIG. The video information can be displayed on a free-form display system made using it.

  The above technical disclosure is intended to be illustrative and not limiting. For example, the above-described embodiments (or one or more aspects of these embodiments) can be used in combination with each other. Other embodiments will be apparent to those of skill in the art upon reviewing the above description. Accordingly, the claims should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are plain English equivalent to the terms “comprising” and “where in”, respectively. It is used as Also, in the following claims, the terms “including” and “comprising” are unlimited, ie, elements other than those listed after such terms in the claims. Any system, device, article or process comprising is considered within the scope of this claim. Further, in the following claims, terms such as “first”, “second” and “third” are used merely as labels, It is not intended to give numerical requirements to things.

Claims (19)

A digitally controlled series configuration system, wherein the digitally controlled series configuration system is:
A power supply for supplying power;
A line driver circuit, wherein the line driver circuit receives power from the power source, the line driver circuit receives control data from a controller system, the line driver circuit drives an output line with current, and the line driver A circuit that modulates the control data with the current; a line driver circuit;
Two or more controlled units connected in a series configuration to the output line, the controlled unit taking the operating power from the current on the output line using a shunt and the controlled unit Each unit demodulates the control data from the output line, and each controlled unit uses the control data and controls at least one local circuit connected to the controlled unit. Unit,
A system of digitally controlled series configuration comprising:   The digitally controlled series configuration system of claim 1, wherein the at least one local circuit comprises a light emitting diode driver circuit.   The digitally controlled series system of claim 1, wherein the line driver modulates the control data with the current using a current ramp up and ramp down.   The digitally controlled series system of claim 1, wherein the line driver causes a current drop away from a rated current level at a specified time to modulate the control data with the current.   Each of the controlled units is connected to a plurality of lighting devices configured in close proximity to each other, and various colors output from the plurality of lighting devices can be combined to generate a broad color spectrum. Item 9. A digitally controlled series configuration system according to Item 1.   The controlled unit operates from the current on the output line by charging the local capacitor when there is sufficient power in the local capacitor, shunting the current and flowing the current back through the output line The digitally controlled series system of claim 1, wherein power is captured.   The digitally controlled series system of claim 1, wherein the controlled unit uses the current on the output line as a reference current.   The digitally controlled series system of claim 1, wherein the controllable lighting unit uses the output line as a heat sink. A method of feeding and controlling two or more electronic units connected to a driver line in a series configuration, the method comprising:
Receiving power from a power source;
Receiving digital control data from the controller system;
Driving the driver line with a DC current having a rated current level;
Modulating the digital control data with the DC current;
Stopping the shunt to capture operating power from the DC current on the output line in an electronic unit connected to the output line;
Demodulating the digital control data from the driver in the electronic unit;
Using the digital control data demodulated from the DC current on the output line to control at least one local circuit connected to the electronic unit;
Including the method.   The method of claim 9, wherein the at least one local circuit comprises a light emitting diode.   The method of claim 9, wherein modulating the digital control data with the DC current includes increasing or decreasing the current around the rated current level.   The electronic unit connected to the output line includes a plurality of lighting devices configured close to each other so that a wide spectrum of colors can be generated by combining various colors transmitted from the plurality of lighting devices. 10. The method of claim 9, comprising.   The electronic unit connected to the output line allows the DC current to flow toward a local capacitor, and when the capacitor is fully charged, shunts the DC current and causes the current to flow again to the output line, The method of claim 9, wherein operating power is taken from the DC current.   The method of claim 9, wherein the electronic unit uses the DC current on the output line as a reference current. The method of claim 9, wherein the electronic unit uses the output line as a heat sink.   The method of claim 9, wherein modulating the digital control data with the DC current comprises modulating an encoded current drop from the rated current level.   The method of claim 9, wherein modulating the digital control data with the DC current comprises modulating an encoded dip from the rated current level.   The method of claim 9, wherein the two or more electronic units each have a unique address. A method of feeding and controlling two or more electronic units connected to an output line in a series configuration, the method comprising:
Including driving a modulated current from a line driver circuit, wherein the driving of the modulated current comprises:
Receiving digital control data from the controller system;
Driving the output line with a DC current having a rated current level;
Modulating the digital control data with the DC current by removing the DC current from the rated current level;
Stopping the shunt to capture operating power from the DC current on the output line in an electronic unit connected to the output line;
Controlling a local circuit in an electronic unit connected to the output line, the control of the local circuit comprising:
Stopping the shunt to capture operating power from the DC current on the output line in the electronic unit connected to the output line;
Demodulating the digital control data from the DC current on the output line in the electronic unit;
Using the digital control data demodulated from the DC current on the output line to control at least one local circuit connected to the electronic unit;
Including the method.