WO2008025214A1 - Lamp controller with a single lamp access function - Google Patents

Abstract

A lamp controller with a single lamp access function for an electric illumination subsection control system includes a content accessable light control switch means (39) which is for converting control commands transmitted in a bus (2) into event control switching signals and single lamp light dimming switching signals, and outputting the signals to a light event setting means (42), and the light event setting means (42) said above which is for decoding the received event control switching signals and single lamp light dimming switching signals from the content accessable light control switch means (39) and light and event data signals set by itself, and outputting the decoded results to a light source driver (34) to drive the light source (35) to be turned on/off and regulate its lightness. By use of the lamp controller, the lamp control will be flexible, the manufacture and the use of the content accessable light control switch means will be simplified, the cost will be reduced, and digital light control systems will be easy to be popularized.

Description

 Lamp controller with single lamp addressing function

Technical field

 The invention relates to the technical field of electric illumination zone control, in particular to a lamp controller with single lamp addressing function, in particular to an electric lighting zone control system, which can set multiple lighting scenes and can accept overall lighting scene control. The command, in turn, is capable of accepting a single lamp control command, a lamp controller having a single lamp addressing function. Background technique

 With the advancement of electronic components and electronic control technology, the electric lighting process has developed into a digital control system, in which the Digital Addressable Lighting Interface (DALI) is referred to in Annex E of IEC60929. ) Most representative. This was originally a specification for fluorescent dimming control, but it was gradually developed into a control system specification covering all electric lighting systems due to its reliability, simplicity, and reasonable price. Especially in the face of worldwide energy and environmental issues, energy-saving technologies are becoming increasingly important, and lighting systems that can be controlled automatically are becoming necessary.

 The digital electric lighting control system was originally an extension of the calculator technology. The lighting control system that uses the serial bus to transmit control information such as the network is very powerful, but the price is too high and unreasonable. Restrictions, only for some special purposes, are not universal.

 The digital addressable lighting interface system was developed successfully in Europe and gradually accepted by the world. Its architecture, consists essentially of a bus power supply, at least one controller, and a light fixture with a digitally addressable light interface receiver. Each digital addressable light loop can control up to 64 individual luminaires, each of which is assigned an address code at initial setup. According to this address, the system can issue instructions for each luminaire separately. However, in practical applications, the luminaires should be grouped first. After storing the group data in the memory of each luminaire, as shown in European Patent EP90100465.6 (USPAT5352957), the instructions can be directly issued for the group. A loop can set up to 16 groups (0~15). Each fixture can belong to several groups at the same time. However, depending on the actual system, some products only allow one group to be set.

The use of the group is very convenient and important. For example, each room is at least one group, so that the controller can control the whole room as a whole, and the controller in the room must also set its control group in advance, so that the instructions can be correctly issued without cluttering. Another example is an office, assuming it includes several rooms and a conference room. In order to meet the requirements of energy saving, each room must be individually controllable, and it can automatically turn off the illumination or reduce the brightness when no one is present. Degree. If the lighting of each room is to be controlled separately, a group code must be assigned separately. The controller and sensor associated with this room must also be set with the same group code. The lights in the conference room may need to be divided into at least three groups, such as the top of the podium, the conference table, and the two sidelights, to accommodate different needs such as speeches, deliberations, multimedia presentations, and briefings. In order to facilitate the direct command of each group of lights, each room can be equipped with a dedicated group controller. As long as the group button of the group controller is pressed, the group of lamps will accept the command. Of course, these connections must be pre-set. OK, otherwise the controller and the controlled luminaire will not be able to connect. For the grouping method of the controller, reference can be made to the German patent DE4327809.4, (USPAT.5544037). The common group controller has four group selection keys.

 After the grouping is completed, each group of lights can be separately adjusted to an appropriate brightness to form an overall lighting scene. Some locations, such as multi-purpose conference rooms, may require several different lighting scenarios to suit different needs. In order to avoid the trouble of frequent adjustment, the lighting scene controller can be used to pre-store the data of each group, brightness and other data related to each lighting scene, and only need to press the scene selection button to retrieve the original design. Fixed, common lighting scene controllers generally have 4 to 8 scene keys to choose from.

 The addressability of digital addressable lighting interface systems is characterized by the grouping, scene setting, and dimming of the entire system. However, the initial grouping, setting the scene, and setting the brightness can be very complicated and require professional and specialized tools.

 A digitally addressable light interface system loop that can have 64 controllers, each with its own address (the sensor is also a controller). Each controller must be pre-set. It has been shown through practical application experience that a digitally addressable lighting interface loop, whose luminaires can only be divided into up to 16 groups, is often insufficiently used, thus creating a limitation. For example, when the number of rooms is a little more or the lighting scene is more complicated, it cannot be handled, and another loop must be added.

 In addition to the simple lighting function in daily life, many places often need to set multiple lighting scenes to meet the actual needs. These needs are sometimes functional, sometimes for energy savings, and sometimes for both. For example: general halls and walkways, all work should be bright when cleaning work, usually half light; merchandise display space, the key theme of the display should be brighter, the background should be darker, to create contrast, highlight the theme, but When doing cleaning work, it should be fully lit; when meeting in the conference room, the lighting on the conference table should be brighter, the surrounding should be darker, when the briefing is made, the whole room should be darker, only the projection screen near the desk should be completely dark. Eli projected images. Other living spaces such as living rooms and restaurants can also use the changes in lighting scenes to create an energy-saving and colorful living atmosphere.

 This overall lighting scene atmosphere, in addition to making people feel comfortable and happy, because the lighting is not always in a state of full light, it also achieves energy-saving purposes.

In order to achieve the control effect of the lighting scene, if the digital addressable lighting interface lighting control system is used, as before As described in the article, each luminaire must be grouped, and each group of lights is adjusted to the required brightness, and then the group brightness of each group is stored in the scene controller, and the scene controller is set back according to the button. Scene. Although the digital addressable lighting interface lighting control system can directly control each luminaire, it is not practical and inconvenient for the average user. The actual lighting control must be performed by means of the scene controller or the group controller.

 Let's take an ordinary conference room as an example to illustrate the lighting layout. As shown in Figure 1, Figure 1 is a schematic diagram of the layout of the conference room lighting.

 The lamps in the whole conference room are classified into the first group, including all the lamps. The lamps on the conference table are classified into the second group 2, including the lamps 2-1, 2-2, 2-3, and the lamps on the wall side are classified. The third group 3, including lamps 3-1, 3-2, 3-3, 3-4, the lamps of the front platform are classified into the fourth group 4, including lamps 4-1, 4-2, 4-3 controller SC There are 4 scene selection buttons and a total button. As long as the scene button is pressed, the entire field light is in place. However, this convenience is based on complex hardware and software systems. The setting procedure is complicated and the price is high. For developing countries that need automatic lighting control technology to cope with energy saving problems, the price is high. It is unacceptable. Therefore, a more economical and easier to use electric lighting control system is highly anticipated.

 The settings of each lighting scene are shown in Table 1 below -

 Table 1

 It can be seen from Table 1 that basically the control of the lighting scene is achieved by changing the brightness of the light source of each luminaire, and grouping the luminaires for the convenience of setting and executing instructions. If the scene brightness setting of each luminaire can be easily performed, and each luminaire can easily receive and execute scene instructions directly, grouping is not necessary, thus eliminating the limitation of up to 16 groups.

In order to relieve the restriction by grouping and to waive the complicated setting procedure, the Chinese Patent Application No. 200610076528.2 proposed by the applicant of the present invention is entitled "Electrical Lighting Control System and Control Method Separated by Painted Repeater" In the patent case, a solution is proposed, which is a reference document of the related patent case of the present invention.

 Table 1 also shows that the change of the brightness of the light source can be full bright, off, simple switching two-stage dimming; can be semi-bright, 3/4 bright, full bright, off and off four-stage dimming; A fine-tuned dimming method, such as: 16-step dimming. Very fine dimming of the 255 steps, as specified by the Digital Addressable Lighting Interface, is often too much and wastes.

 The light level of each light scene can be completed by the light scene setting device 42, and the light scene control command can be directly executed by the content addressable light control switch 39. These actions are transparent and direct, and do not require complicated settings. program.

 In order to achieve each luminaire, the control command can be directly received without setting a program, and another name proposed by the applicant of the present invention and the application is "a luminaire control function applied to the electric lighting partition control system. The "Unit" application proposes a technical solution for controlling the light with a content addressable light control switch.

 The content addressable technology is a memory addressing method developed on the basis of random access memory. Compared with the traditional memory device, the method of pointing to an address and then finding the memory content is different, and the input information data can be The content addressable all the data in the memory device, and the comparison is performed at the same time, and the correct address of the relevant memory is directly determined by the input information content. This fast addressing performance is very important for network communication, and its operation can be performed by pure hardware. Complete without having to resort to a microcomputer or central processing unit, without taking up software operating time. Content Addressable technology also plays an important role in information compression coding and decoding and image processing. As shown in U.S. Patent No. 3,402,394, 34,1985.

 The content addressable light control switch for electric lighting control uses content addressable technology to directly convert the command for driving the light source into the corresponding switching signal according to the instruction content, and each switching signal starts its corresponding , a preset light source driving circuit to complete the expected action of each instruction.

 This content addressable light control switch can be fabricated from a semiconductor integrated circuit without the need for a microcomputer or central processor, so the price can be reduced. The practical application is conceptually the same as a simple selection switch, so no special personnel training process is required and no special tools or software knowledge is required.

 The light scene setting device is used for providing a connection between the content addressable light control switch and the light source driving circuit, and is integrated with the driving circuit of each light source, and the actual circuit is driven by the light source driving circuit and The dimming effect is different, but for the user, it is only necessary to perform the action of dialing the code to set the brightness of each scene, so it is easy to operate, and has the friendly features of plug and play.

However, in addition to controlling the overall lighting scene, in some more personal spaces, such as rooms in high-end hotels, living rooms in homes, etc., it is often necessary to switch or dim the individual lamps to meet everyone. The same needs. Some special luminaires, such as chandeliers, often require special treatment. In order to meet the need for separate control of individual luminaires, the above-mentioned content addressable light control switches must have single-lamp addressing. .

 The content addressable memory device has a function of setting an address, which means a program for writing address data to a content addressable memory device. The conventional method of writing data in a content addressable memory is to use a word line. Line, control the word line to be written, activate the memory word line, open the memory cell write gate of the relevant word line, and then write the data side by side into each memory unit of the word line.

 This traditional write procedure will complicate the circuit architecture and clock controller of the content addressable light control switch, requiring control by the microcomputer controller. This will increase the price of the product. In order to achieve the purpose of improving lighting quality and energy saving, price is an important factor. Therefore, how to increase the addressing function while reducing the price and being easy to use is an important issue. Summary of the invention

 (1) Technical problems to be solved

 In view of this, the main object of the present invention is to provide a lamp controller having a single lamp addressing function applied to an electric lighting zone control system, so that the lamp can receive single lamp control in addition to receiving broadcast and interval control commands. The control of the luminaire is more flexible, more suitable for practical needs, and the manufacture and use of the content addressable light control switch is more simplified, so as to reduce the cost and make the digital lighting control system more popular, which is beneficial to digital lighting. Control systems benefit from improved lighting quality and lighting energy savings.

 (ii) Technical solutions

 In order to achieve the above object, the technical solution of the present invention is achieved as follows:

 A lamp controller for use in an electric lighting zone control system having a single lamp addressing function, the lamp controller comprising:

 a content addressable light control switch device for converting a control command transmitted on the bus into a scene control switch signal and a single lamp dimmer switch signal, and outputting to the light scene setting device;

 The light scene setting device is configured to decode the scene control switch signal and the single lamp dimmer switch signal received from the content addressable light control switch device, and decode the light scene data signal set by itself, and decode the decoding result Output to the light source driving device, driving the light source switch and brightness.

 The content addressable light control switch device includes:

Content addressable memory device, used to store and compare the interval instructions with the address set by the fixture Ordering, outputting the comparison result to the light scene control device through the latch;

 A content addressable memory setting device for setting address bit data in a content addressable memory device and a specific address related instruction of the luminaire.

 The content addressable light control switch device is fabricated by a single core semiconductor integrated circuit, and the content addressable memory device stores one instruction per line when storing control instruction data, and at least one row of stored control instruction data is a single Light control command.

 The single lamp control command line has at least one bit being an address bit.

 The content addressable memory device includes a plurality of memory units including an address-related memory unit and a data-related memory unit;

 The address bits of the content addressable memory device are the second column to the fifth column of the memory array of the content addressable light control switch device memory unit, respectively: the second column is the address first bit Al, the third The address is the second bit A2 of the address, the fourth column is the third bit A4 of the address, and the fifth column is the fourth bit A8 of the address.

 The four addressing bits A8, A4, A2, A1 are used to set 16 addresses.

 The content controllable light control switch device has four rows of light control commands associated with a specific address in the memory array, and is respectively turned on, off, brightened, and dimmed.

 The address-related memory unit in the content addressable memory device uses a column bit write mode when setting an address, the memory unit has two nodes, the first node stores data, and the second node is Complementary data for storing data;

 The first node is connected to the gate of the first comparison transistor, the second node is connected to the gate of the second comparison transistor, and the first node is simultaneously connected to the output of the corresponding address bit D-type latch via the first bit line The second node is simultaneously connected to the complementary output terminal of the corresponding address bit D-type latch via the second bit line, and the input end of the address bit D-type latch is a logic value set by the address setting device; The bit line and the second bit line are write lines of the same address bit of each address related instruction, and the source of the second comparison transistor is connected to the output end corresponding to the input instruction shift register, the first comparison transistor The source is connected to the complement of the corresponding output of the input instruction shift register; the first comparison transistor is connected to the drain of the second comparison transistor, and is connected to the gate of a comparison line driving transistor, The drain of the line drive transistor is logically grounded, and the source of the line drive transistor is connected to the comparison line. The comparison line is connected to the logic high level via a limiting current device, and the source of each of the comparison lines drives the transistor in the same command line. Extremely connected to peers On the line.

The content addressable address-related memory unit in the memory device, the same bit address memory unit is connected to the corresponding address bit D-type latch via the address write line, and the shared D-type latch is memory, and Each address bit The memory unit is simplified and cancelled.

 The content addressable memory setting device is a dial switch or a jumper device.

(3) Beneficial effects

 As can be seen from the above technical solutions, the present invention has the following beneficial effects:

 1. The invention adds a function module with independent addressing function to the existing lamp controller, so that the lamp controller has a separate addressing function, realizes lighting control of a specific lamp, and thus the lamp can receive broadcast and The single-lamp control can also be accepted outside the interval control command, which makes the control of the luminaire more flexible, and more satisfies the actual need to improve the lighting quality by controlling the lighting of individual lamps.

 2. The lamp controller with single lamp addressing function provided by the invention not only pays attention to the functional considerations, but also pays special attention to the price reduction, so that the manufacture and use of the content addressable light control switch are more simplified and reduced. The cost makes the digital lighting control system more popular, which in turn helps the digital lighting control system to improve the lighting quality and lighting energy saving.

 3. The lamp controller with single lamp addressing function provided by the invention has the single lamp control function in addition to the overall control function of the lighting scene in the electric lighting zone control system, and is more meticulous with the special single lamp. The dimming process makes the choice of lamps simple and flexible. In addition, it is also possible to make various lamps and lanterns develop their strengths and give full play to individual economic benefits.

DRAWINGS

 Figure 1 is a schematic diagram of a layout of a conference room lighting;

 2 is a block diagram of a lamp controller with a single lamp addressing function provided by the present invention;

 3 is a block diagram of a content addressable light control switch device in a lamp controller provided by the present invention; FIG. 4 is a circuit diagram of a content addressable memory device in a content addressable light control device provided by the present invention;

 5 is a circuit diagram of a column write mode for a content addressable memory device in a content addressable light control switch device provided by the present invention;

 6 is a simplified circuit diagram of a column write mode employed by a content addressable memory device in a content addressable light control switch device provided by the present invention;

FIG. 7 is a block diagram of a light scene setting device in a lamp controller provided by the present invention. detailed description

 In order to make the objects, the technical solutions and the advantages of the present invention more comprehensible, the present invention will be further described in detail below with reference to the accompanying drawings.

 As shown in FIG. 2, FIG. 2 is a block diagram of a lamp controller with a single lamp addressing function provided by the present invention. The lamp controller includes at least a content addressable light control switch device 39 and a light scene setting device 42.

 The content addressable light control switch device 39 is configured to convert the control command transmitted on the bus 2 into a scene control switch signal and a single lamp dimmer switch signal, and output to the light scene setting device 42;

 The light scene setting device 42 is configured to decode the scene control switch signal and the single light dimmer switch signal received from the content addressable light control switch device 39, and decode the light scene data signal set by itself, and decode The result is output to the light source driving device 34, which drives the switch and brightness of the light source 35. Referring again to FIG. 2, the lamp controller further includes an optical isolator 31, an information data restoring device 41, shift registers 37 and 38, a clock management device 40, a system command decoding device 44, a latch 43 and a light source driving device. 34.

 The optical isolator 31 is configured to input a lighting scene control command transmitted on the bus to the information data restoring device 41.

 The information data restoration device 41 is for restoring the light scene control command input from the optical isolator 31, and outputs the restored digital data to the shift registers 37 and 38, and the clock signal is output to the clock management device 40.

 The shift registers 37 and 38 are used to store the digital data restored by the information data restoring device, and output the system command clamp byte in the digital data to the system command decoding device 44 to instruct the lower byte segment instruction in the system command digital data. Output to the content addressable light control switch device 39. The shift register 37 is a system instruction shift register, and the shift register 38 is an interval instruction shift register. Interval instruction shift register 38 is shared with the lower byte of system instruction shift register 37.

 The system instruction decoding means 44 is operative to decode the system instruction high byte input by the system instruction shift register 37, output the coincidence information or remove the function information to the content addressable light control switch means 39 in accordance with the decoding result.

 The instruction entering the information processor 32, if it is a 1-byte interval instruction, the system instruction decoding means 44 will directly output the coincidence information so that the content addressable light control switch device 39 is in the execution state.

The content addressable light control switch device 39 is used for the interval in which the interval instruction shift register 38 is input in parallel. The command performs the comparison decoding. If there is a matching complete instruction, the light control signal for the luminaire is generated and output to the light scene control device 42 through the latch 43. The content addressable light control switch device 39 is generally made of a single core semiconductor integrated circuit.

 The latch 43, is for storing information input by the content addressable light control switch device 39, and outputs information input by the content addressable light control switch device 39 to the light scene control device 42.

 The light source driving device 34 is configured to drive the light source driving device according to the decoding result received from the light scene control device 42. The information data restoring means 41, the shift registers 37 and 38, the clock management means 40, the system command decoding means 44, the content addressable light control switch means 39 and the latch 43 constitute an information processor 32 for the light control The light scene control command input by the isolator is decoded, and the light control switch signal generated by the decoding is output to the light scene control device 42 to realize the light control of the light fixture 35. Referring again to FIG. 2, the above-described content addressable light control switching device 39 includes a content addressable memory device 390 and a content addressable memory setting device 391.

 In the information processor 32, the upper byte of the system instruction is decoded by the system instruction decoding device 44, and the low order byte and the interval instruction of the system instruction are compared and decoded by the content addressable light control switch 39, and The switch signal is output to the decoding device 33 via the latch 43.

 The content addressable memory device 390 is configured to store and compare the instructions related to the specific address of the interval instruction portion to the luminaire, and output the comparison result to the light scene control device 42 through the latch 43. The content addressable memory setting device 391 is used to set the content addressable memory device 390. The content addressable memory setting device 391 can be a dial switch or the like, such as a jumper device. Please refer to FIG. 3. FIG. 3 is a block diagram of a content addressable light control switch device in a lamp controller provided by the present invention. The content addressable light control switch device 39 is fabricated by a single core semiconductor integrated circuit, and the content addressable memory device 390 stores one instruction per line when storing control command data, and at least one row of stored control command data For single lamp control commands. The single lamp control command line has at least one bit being an address bit.

The content addressable memory device 390 includes a plurality of memory units including an address-related memory unit and a data-related memory unit; the content addressable address of the memory device is available for content The second column to the fifth column of the memory array of the memory control switch device memory unit are: the second column is the address first bit A1, the third column is the address second bit A2, and the fourth column is the address third bit. A4, column 5 is the fourth digit of the address A8. The four addressing bits A8, A4, A2, Al are used to set 16 addresses.

 The content controllable light control switch device has four rows of light control commands associated with a specific address in the memory array, and is respectively turned on, off, brightened, and dimmed.

 The content addressable 0th through 5th range of the memory array of the light control switch device is valid for all fixtures of the executable interval command. The instructions in lines 6 through 9 are only valid for fixtures that match the specific address.

 The two-phase lighting scene control command transmitted on the digital bus 2 enters the information processor 32 via the optical isolator 31. The digital information processor 32 decodes the received command and inputs the scene setting means 42 for the light control action. 36 in the scene setting device 42 is a light setting device such as a 2-digit DIP switch. It can be pre- or on-site planning, 2-digit dial switch, and you can provide 4 kinds of light brightness setting options for each light scene. The setting action is clear and direct, easy to operate, and can be set during deployment. It's easy to adjust at any time. The decoding device 33, after decoding according to the setting of the light setting device 36, outputs a switch or a light brightness control signal to the light source driving device 34 to drive the light source 35.

 The light source 35 can also be an incandescent lamp, a halogen lamp, a fluorescent lamp, an energy saving lamp, a high pressure gas discharge lamp (HID), a light emitting diode (LED), or the like. The light source driving device 34 of the light source 35 receives the control signal output from the control decoder 33 to switch or dim the light source 35. The light source driving device 34 may be a ballast, an electronic transformer, or a relay, depending on the light source 35 and actual needs. The power line 1 supplies power to the light source 35 via the light source driver 34. Since the control of the individual luminaires is more necessary when the user is immersed in the environment, the addressing device of the luminaire is disposed in the instruction processing area of the luminaire controller section, as shown in FIG. 2, including the interval instruction shift register 38, and The content of the interval instruction for decoding can address portions of the light control switching device 39.

 The content addressable memory device 390 in the content addressable light control switch device 39 is a portion associated with a particular lamp address setting and is the core of the present invention.

 For ease of explanation, the present embodiment will employ a light scene command that is compatible with the Digital Addressable Light Interface Specification (DALI), as shown in Tables 2 and 3, where Table 2 is the system command and Table 3 is the interval command.

For example, the system-wide broadcast command of the present invention can be set to two bytes, and the first byte is FF, as shown in Table 2 - Turn off FF00 11111111 00000000

 All FF05 11111111 00000101 Scene 1 FF11 11111111 00010001 Scene 2 FF12 11111111 00010010 Scene 3 FF13 11111111 00010011 Scene 4 FF14 11111111 00010100

(J can be specified as a single byte, as shown in Table 3:

 Shutdown 00 00000000

 3ι redundancy 05 00000101

 Scene 1 11 00010001

 Scene 2 12 00010010

 Scene 3 13 00010011

 Scene 4 14 00010100

 Table 3 The system command decoder 44 technique of Figure 2 is a technique that is readily apparent to those of ordinary skill in the art, such as by means of AND gates, repulsions or gates, and with the manual addressing of the present invention. The addressing means are not directly related, and are simplified and omitted in FIG. 3 for simplicity.

 Referring again to FIG. 3, the content addressable light control switch device 39 directly decodes the digital command according to the contents of the command, and converts it into a switch signal via a latch 43: m0 on (full light), ml off, M2 scene 1, m3 scene 2, m4 scene 3, m5 scene 4. M6, m7, m8, m9 are the switching signal lines associated with a specific address, m6 is on (full light), l is off, m8 is dimming, m9 is dimming. After each of the switch signals passes through the light scene setting device 42, the light source driving device 34 is driven to drive the light source 35. The light source 35 can be a halogen lamp, a tubular fluorescent lamp, a compact energy-saving lamp, a light-emitting diode, etc., and the light source driving device 34 can be a relay, an electronic transformer, a ballast, etc., and the light scene setting device 42 can be set via the light setting device 36. , set the brightness of each light source in each lighting scene.

The content addressable light control switch device 39 has various related commands stored therein, and the memory unit is made of a read only memory or other non-volatile memory device, and each memory unit has a comparison with the received command bits. The device, the comparison result drives the comparison line via a driving device. In the content addressable light control switch device 39 Among the switching instructions of the memory, the overall lighting controller includes: ON (full bright), off, scene 1, scene 2, scene 3, scene 4 and other lighting control commands, and the switching signals belonging to the single lamp control are _m 6, m7 , m8, m9.

 After the digital light control command enters the information data restoration device 41 via the information transmission bus 2 and restores the data and the clock signal, the digital data enters the interval instruction shift register 38, and the clock signal enters the clock controller 40. In the light control command, the high byte of the 2-byte instruction 37 as shown in FIG. 2 is the system instruction part of the communication protocol, and the low byte of 37 is equivalent to the byte of the interval instruction 38 is its actual lighting control part. The data of byte 38 is aligned with the read-only memory instruction data of the address-addressable 39, and the fully matched (output) line generates a corresponding output signal (m0-m9), and is detected at 41. After two stop bits are obtained, a latch pulse L is generated, latched into the D-type latch 43, fed into the decoding device 33 of the light scene setting device 42 via the D-type latch 43, and driven after decoding. Light source driver 34 and light source 35.

 The data latch of the D-type latch 43 is controlled by the lock controller LC, when m0~! N9 can be latched when there is a match line. R is the current limiting resistor when charging m0-m9. When the comparison is made, the memory cells of each column are simultaneously compared, and the memory cells that do not match the matching will pull the related m0-m9 comparison line to the low level, and only the columns are consistent. The m0-m9 comparison line can maintain a high level.

 The 0th line to the 5th line interval instruction of the memory array of the content addressable light control switch device 39 is valid for all the lamps of the executable interval instruction; the 6th to 9th lines are associated with the instruction of the specific address, line 6 The memory cells in the second column to the fifth column of the ninth row are the addressing bits 390, which are: the second column is the address first bit A1, the third column is the address second bit A2, and the fourth column is the address third. Bit A4, column 5 is the fourth bit of the address A8. A total of 16 addresses can be set for 4 address bits A8, A4, A2, and A1.

 There are four address-related instructions in this embodiment, which are shown in Table 4 below:

 Table 4

Each luminaire can be selected with a controller capable of addressing capability or a controller without addressing capability. A controller without addressing capability can only perform interval command actions, receive system broadcast commands and interval commands, and select The addressable controller can accept the single lamp control command. For the addressable lamp, the switch can be switched on and the brightness can be adjusted up or down. The setting of the single lamp address is performed by the dial switches SA8, SA4, SA2, and SAl. The data values of the input terminals DA8, DA4, DA2, and DAI of the D-type latch are set by the dialing codes SA8, SA4, SA2, and SAl. The setting is determined and locked into the latch when the system is powered up. As shown in FIG. 4, FIG. 4 is a circuit diagram of a content addressable memory device in a content addressable light control switch device provided by the present invention. Two of the inverters 303, 304 form a bistable memory cell C. When the memory data bit line AB is at a high level, ^" is a low level, and if the word line W is at a high level, the write triode is written. When 301, 302 is turned on, the input of the first node inverter 303 of the memory is high, and the output thereof is low for the second node, and this state will be latched. At this time, the comparator 305 is 305. In the open state, the comparator transistor 306 is turned on.

 If the input addressing data bit line B is at a high level, ¥ is low, that is, when the input data B is the same as the stored data AB, the high level of B cannot be broken by the low level control of the second node. The transistor 305 of the state is introduced into the gate of the driving transistor 307 of the comparison line m, and the transistor 307 is also in an open state, and the comparison line m is kept at a high level.

 If the input data bit line B is low level and ¥ is high level, then the high level of the ¥ will be turned on.

306 is fed into the gate of transistor 307, turning 307 on, and the comparison line m is pulled low. That is, when the data stored in the first node AB does not match the B, the m line of the comparison line is pulled low; when the comparison matches, the level is kept high. If each memory cell of the same word line matches, the m line of the comparison line can be kept at a high level.

The AB bit line is the address data line, the Β bit line is the corresponding instruction bit line, W is the word line write line, m is the comparison line, and R is the current limiting resistor. As shown in FIG. 5, FIG. 5 is a circuit diagram of a column write mode for a content addressable memory device in a content addressable light control switch device according to the present invention. Since in the content addressable light control switch device 39, the address-related memory cells have the same data for the same column, the word line can be omitted, and the address data to be stored is directly written by the bit line to Memory unit _C.

 In FIG. 5, 308 is a D-type latch, and the logic level of the input terminal D is determined by the opening and closing of the address setting switch SA. When the power is turned on, the level of the capacitor K is gradually increased, and the single trigger is activated. The pulses generated by the steady state oscillators 309, 309 lock the SA set logic data D into the latch 308, and the address memory cells in the same column are also set. The push button switch 310 is used to activate the 309 update setting when some need to manually test or change the address.

The memory unit has two nodes, the input of the first node 303 is for storing data, and the output of the second node 303 is The end is the complementary data that stores the data.

 The first node is connected to the gate of the first comparison transistor 306, the second node is connected to the gate of the second comparison transistor 305, and the first node is simultaneously connected to the corresponding address bit D-type latch via the first bit line AB At the output end of the 308, the second node is simultaneously connected to the complementary output terminal of the corresponding address bit D-type latch via the second bit line, and the input terminal of the address bit D-type latch is set by the address setting device. Logical value. The first bit line AB and the second bit line are write lines of the same address bit of each address related instruction, and the source of the second comparison transistor 305 is connected to the output corresponding to the input instruction shift register via the instruction data line B. The source of the first comparison transistor is connected to the complement of the bit output corresponding to the input instruction shift register via the instruction data complement line B, and the drains of the first comparison transistor 306 and the second comparison transistor 305 Connected to a gate of a comparison line driving transistor 307, the drain line m drives the drain of the transistor 307 to be logically grounded, and the source of the comparison line driving transistor 307 is connected to the comparison line, and the comparison line is limited. The current device R is connected to a logic high potential, and the source of each of the comparison line driving transistors of the same command line is connected to the peer comparison line.

 The content addressable address-related memory unit in the memory device, the same bit address memory unit is connected to the corresponding address bit D-type latch via the address write line, and the shared D-type latch is memory, and The memory unit for each address bit is simplified and cancelled. As shown in FIG. 6, FIG. 6 is a simplified circuit diagram of a column write mode employed by the content addressable memory device in the content addressable light control switch device of the present invention. Since the address data has been saved by the latch 308, the memory cells 303, 304 can be omitted in practice. Compared with the circuit of Fig. 4 which is similar to the random access memory, the circuit shown in Fig. 6 is simplified, so that the overall content addressable light control switch device 39 is further streamlined in the process and layout, which is advantageous for reducing the manufacturing cost. As shown in FIG. 7, FIG. 7 is a block diagram of a light scene setting device in a lamp controller provided by the present invention. Each lighting scene can have 100% (full brightness), 75%, 50%, 0% (off) four setting options, each scene has 2 digits of the dial switch as shown in Figure 7 of SS1, SS2 , SS3, SS4 are used to set the brightness of the light source in each lighting scene.

For example, when the control command is 00010001, the switch control signal m2 of the light scene 1 is at a high level, and the remaining m0, ml, m3, m4, m5, m6, m7, m8, m9 are all low level, and the m2 is high level. The selection circuit 401 is in the execution function state, and the low level of m3, m4, m5 causes the remaining selection circuits 402, 403, and 404 to be in the removal function state. When the SS11 and SS12 are closed in the light scene setting switch SS1, Loss of the door 401-1 The output is high, and the other outputs 401-2, 401-3, 401-4 are low. The high level of 401-1 enters OR gate 406-1 and is locked into parallel input parallel. In the output bidirectional shift register 405, the output terminal Q1 of 405 is at a high level, and the light source is 100% fully illuminated.

 If SS11 is closed and SS12 is open, the output of AND gate 401-2 is high. This high level inputs OR gate 406-2 and inputs D2 of 405, causing source 35 to be 75% bright. The rest of the brightness selection and so on. The m8, πι9 level shifts the shift register 405 up or down, causing the output terminals Ql, Q2, Q3, Q4 of 405 to move up or down, thereby dimming or dimming the source 35.

 M6 and m7 jointly control the switching of the light source with m0, ml via OR gates 407, 408, respectively. Either m0 or m6 can turn on the light source 35, ml, m7 can turn off the light source 35. Figure 7 shows only the function description of a 4-segment dimming lighting scene setting device that can be used. Others such as 2-stage dimming and 16-segment dimming are also available, depending on actual needs.

 The lighting scene control command m2-m5 is passed through the OR gate 409 and the dimming command m8, and the dimming command m9 is entered into the decoding circuit 410 to control the operation mode of the bidirectional shift register 405. The register 405 can be an integrated circuit similar to 74F194. When any of m2, m3, m4, m5 is high level, 405 is a parallel input mode, and when tn8 is high level, it is an up shift mode, and when m9 is a high level, it is a direction. In the lower shift mode, the 405 can be wired as a ring shift. The above embodiments are merely illustrative of one way to independently control a single lamp. Due to the need for independently controlled luminaires, which are usually special luminaires, require finer dimming capabilities, such as 16th order dimming. This dimming technique is not difficult to achieve in the lighting process. For example, the DALI system regulates the use of wavelength-width modulation (PWM) to achieve 256-step dimming. Applying this more sophisticated dimming technology to the lighting scene setting device and the light source driver, the fine dimming requirements can be achieved. This kind of simple lighting control for general luminaires, finer dimming of special luminaires, the price of the overall lighting system can be well controlled, no waste of quality and no waste, and no reduction The quality of the lighting of the special lights. It provides a simple and compatible way to maximize economic benefits. The above described specific embodiments of the present invention are described in detail, and are not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.

Claims

Rights request

1. A lamp controller for use in an electric lighting zone control system having a single lamp addressing function, wherein the lamp controller comprises:

 The content addressable light control switch device is configured to convert the control command transmitted on the bus into a scene control switch signal and a single lamp dimmer switch signal, and output the device to the light scene setting device;

 The lighting scene setting device is configured to decode the scene control switch signal and the single lamp dimming signal received from the content addressable light control switch device, and decode the light scene data signal set by itself, and decode The result is output to the light source driving device, which drives the switch and brightness of the light source.

 2. The luminaire controller of claim 1, wherein the content addressable light control switch device comprises:

 a content addressable memory device, configured to store and compare the instructions related to the interval instruction and the address set by the light fixture, and output the comparison result to the light scene control device through the latch;

 A content addressable memory setting device for setting address bit data in a content addressable memory device and a specific address related instruction of the luminaire.

 3. The luminaire controller for use in an electric lighting zone control system having a single lamp addressing function according to claim 1, wherein

 The content addressable light control switch device is fabricated by a single core semiconductor integrated circuit, and the content addressable memory device stores one instruction per line when storing control instruction data, and at least one row of stored control instruction data is a single Light control command.

 4. The luminaire controller of claim 3, wherein the single-lamp control command line has at least one bit being an address bit.

 5. A lamp controller for use in an electric lighting zone control system having a single lamp addressing function according to claim 2 or 4, characterized in that

 The content addressable memory device includes a plurality of memory units including an address-related memory unit and a data-related memory unit;

The address bits of the content addressable memory device are the second column to the fifth column of the memory array of the content addressable light control device memory unit, respectively: the second column is the address first bit Al, the first The third column is the second bit A2 of the address, the fourth column is the third bit A4 of the address, and the fifth column is the fourth bit A8 of the address.

6. The lamp controller for use in an electric lighting zone control system having a single lamp addressing function according to claim 5, wherein said four addressing bits A8, A4, A2, A1 are used to set 16 Addresses.

 7. The luminaire controller for an electric lighting zone control system having a single lamp addressing function according to claim 5, wherein said content addressable light control switch device has a memory array associated with a specific address The light control command has 4 lines, which are 4 commands for turning on, off, dimming, and dimming.

 8. The luminaire controller for use in an electric lighting zone control system having a single lamp addressing function according to claim 5, wherein

 The address-related memory unit in the content addressable memory device adopts a column-by-bit write mode when setting an address, the memory unit has two nodes, the first node is storing data, and the second node is storing Complementary data of data;

 The first node is connected to the gate of the first comparison transistor, the second node is connected to the gate of the second comparison transistor, and the first node is simultaneously connected to the output of the corresponding address bit D-type latch via the first bit line The second node is simultaneously connected to the complementary output terminal of the corresponding address bit D-type latch via the second bit line, and the input end of the address bit D-type latch is a logic value set by the address setting device; The bit line and the second bit line are write lines of the same address bit of each address related instruction, and the source of the second comparison transistor is connected to the output end corresponding to the input instruction shift register, the first to the triode The source is connected to the complement of the corresponding output of the input instruction shift register; the first comparison transistor is connected to the drain of the second comparison transistor, and is connected to the gate of a comparison line driving transistor, The drain of the line drive transistor is logically grounded, and the source of the line drive transistor is connected to the comparison line. The comparison line is connected to the logic high level via a limiting current device, and the source of each of the comparison lines drives the transistor in the same command line. Extremely average to peer ratio On the line.

 9. The lamp controller for use in an electric lighting zone control system having a single lamp addressing function according to claim 8, wherein said content addressable memory device has an address-related memory unit, the same bit The address memory unit is connected to the corresponding address bit D-type latch via the address write line, the shared D-type latch is memory, and the memory unit of each address bit is simplified and cancelled.

 10. The luminaire controller of claim 2, wherein the content addressable memory setting device is a dial switch or a jumper device.