阅读说明：本技术 跨隔离势垒的电源配置 (Power supply configuration across isolation barrier ) 是由 B·克劳伯格 方玉红 于 2020-03-25 设计创作，主要内容包括：一种设备、系统和方法配置通电设备的电源。该通电设备包括数字可寻址照明接口(DALI),DALI连接到要由电源供电的负载。通电设备包括隔离器。通电设备包括控制器,该控制器定位在隔离器的初级侧。控制器被配置为生成第一信号,以选择是以零电流值还是最大电流值向DALI供电。控制器进一步被配置为生成第二信号,从而以零电流值和最大电流值之间的所选择的电流值向DALI供电。(An apparatus, system, and method configure a power supply of a powered device. The powered device includes a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by a power source. The powered device includes an isolator. The powered device includes a controller positioned on the primary side of the isolator. The controller is configured to generate a first signal to select whether to power the DALI at a zero current value or a maximum current value. The controller is further configured to generate a second signal to power the DALI at a selected current value between the zero current value and the maximum current value.)

1. A powered device, comprising:

a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by a power source;

an isolator; and

a controller positioned on a primary side of the isolator, the controller configured to generate a first signal to select whether to power the isolator to render the isolator conductive or non-conductive, wherein the DALI has a maximum current value when the isolator is conductive and is at a zero current value when the isolator is non-conductive, the controller further configured to generate a modulated second signal to power the isolator to render the isolator conductive with a duty cycle and a frequency, and wherein the DALI has a selected current value between the zero current value and the maximum current value based on the modulated second signal.

2. The powered device of claim 1, wherein the isolator is an opto-isolator.

3. The powered device of claim 1, wherein the power source is a DC power source from a secondary winding of a transformer.

4. The power-on device of claim 1, wherein the modulated second signal is a Pulse Width Modulated (PWM) signal having a frequency corresponding to the selected current value.

5. The powered device of claim 1, further comprising:

a buck converter to receive a voltage reference based current reference based on the second signal, the buck converter configured to output a fixed voltage to the DALI.

6. The powered device of claim 5, further comprising:

a first resistor having a first resistance; and

a second resistor having a second resistance greater than the first resistance by a predetermined difference,

wherein a voltage between the first resistor and the second resistor corresponds to a modulation corresponding to the selected current value.

7. The powered device of claim 6, further comprising:

a capacitor configured to filter an input of the second resistor together with the second resistor.

8. The energization apparatus according to claim 1, wherein the maximum current value is 110 mA.

9. The powered device of claim 1, wherein the load is a Light Emitting Diode (LED).

10. A method, comprising:

generating a first signal to select whether to power an isolator to render the isolator conductive or non-conductive, wherein a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by a power source has a maximum current value when the isolator is conductive and the DALI is at a zero current value when the isolator is non-conductive; and

generating a modulated second signal to select power to the isolator to turn on the isolator with a duty cycle and a frequency, and based on the modulated second signal, the DALI has a selected current value between the zero current value and the maximum current value.

11. The method of claim 10, wherein the modulated second signal is a Pulse Width Modulated (PWM) signal having a frequency corresponding to the selected current value.

12. The method of claim 10, further comprising:

receiving, at a buck converter, a current reference based on a voltage reference based on the second signal; and

outputting, by the buck converter, a fixed voltage to the DALI.

13. The method of claim 12, wherein a voltage between a first resistor having a first resistance and a second resistor having a second resistance greater than the first resistance by a predetermined difference corresponds to a modulation corresponding to the selected current value.

14. The method of claim 13, further comprising:

filtering an input of the second resistor through a capacitor and the second resistor.

15. A powered device, comprising:

a power source;

a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by the auxiliary power source;

an optical isolator;

a microprocessor positioned on a primary side of the opto-isolator, the microprocessor configured to generate an activation drive signal to select whether to power the isolator to render the isolator conductive or non-conductive, wherein the DALI has a maximum current value when the isolator is conductive, the microprocessor further configured to generate a Pulse Width Modulated (PWM) signal to select power to the isolator to render the isolator conductive with a duty cycle and frequency, and wherein the DALI has a selected current value between a zero current value and the maximum current value based on the modulated second signal; and

a buck converter to receive a reference current based on the PWM signal to generate a fixed voltage corresponding to the selected current value provided to the DALI.

Background

The power supply may provide power to various components of the electronic device. For example, the electronic device may include an illumination component (e.g., a Light Emitting Diode (LED)) to form the illumination device. The lighting device may be configured in a variety of different ways. For example, the lighting device may be configured as a connected lighting system. Connected lighting systems may utilize different types of driver devices, such as intelligent driver devices that provide signaling to different lighting loads including sensors that interpret the signals. Such connected lighting systems may utilize a self-powered Digital Addressable Lighting Interface (DALI). DALI may involve automatic control of lighting using a network-based system. With DALI, one or more passive DALI loads may be connected via the interface without the need to provide a separate control component for each lighting load. Many different types of lighting devices may utilize DALI and the automatic control provided by DALI.

In conventional lighting devices, certain LED drivers with DALI interfaces include an onboard current source (e.g., a DALI power supply). The conventional current setting for the current sources in these LED drivers is about 55 mA. However, implementations of lighting devices with LED drivers and DALI interfaces may use higher currents. For example, a current setting of about 110mA or greater may be used in these implementations. One way to accommodate different current settings is to manufacture the same product with different versions of the power supply. However, this approach may be more costly and more restrictive since the pre-selected current setting is the only option. For example, lower currents may be used for standard implementations, but not for implementations requiring higher currents. In another example, higher currents may create backward compatibility issues. Choosing a higher current may also cause problems related to compliance with the DALI standard, which specifies a maximum current of 250 mA. If multiple LED drivers are connected to the same DALI bus, the power supply becomes additive and can result in exceeding the 250mA DALI limit (e.g., any more than two LED drivers operating at 110mA will exceed the 250mA DALI limit).

Furthermore, a conventional method of switching on or off the current supply is to utilize a microprocessor or controller that generates a signal to indicate when current is to be provided. In one approach, the conventional approach may require an isolation interface, where the microprocessor is disposed on one side of the isolation interface and the signal must cross the isolation barrier (isolation barrier) of the isolation interface. For example, the isolation interface may be an optical isolator. The opto-isolator can be turned on and off to render the photodiode of the opto-isolator conductive or non-conductive, thereby turning the current source on or off, respectively. However, this only allows the use of a single current setting, which faces the disadvantages described above. If the current setting is variable and selectable, then the method of achieving this is to introduce a second opto-isolator. Thus, a first opto-isolator can be used to switch a current source on or off, while a second opto-isolator can be used to select the value of the current provided by the switched-on current source.

The introduction of a second opto-isolator, when considered from a single scale, can be shown to be cost-effective as a solution to the problem of selecting a variable current setting for a DALI current source. However, when considering the production scale where the production and sales volume of products is large (e.g., millions of stations), the introduction of an additional optical isolator becomes a major cost. Therefore, any part of the circuit that can be simplified or reduced in cost is very important.

Disclosure of Invention

It is an object of an exemplary embodiment to provide a powered device that configures a power supply. The powered device includes a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by the power source. The powered device includes an isolator. The powered device includes a controller positioned on a primary side of the isolator. The controller is configured to generate a first signal to select whether to power the DALI at a zero current value or a maximum current value. The controller is further configured to generate a second signal to power the DALI at a selected current value between the zero current value and the maximum current value.

It is an object of an exemplary embodiment to provide a method for configuring a power supply. The method includes generating a first signal to select whether to power a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by a power source at a zero current value or a maximum current value. The method includes generating a second signal to select to provide power to the DALI at a selected current value between a zero current value and a maximum current value.

It is an object of an exemplary embodiment to provide a powered device that configures a power supply. The powered device includes a power supply, a Digital Addressable Lighting Interface (DALI) connected to a load to be powered by an auxiliary power supply, and an opto-isolator. The power-on device includes a microprocessor located on the primary side of an opto-isolator. The microprocessor is configured to generate an activation drive signal to select whether to power the DALI at a zero current value or a maximum current value. The microprocessor is further configured to generate a Pulse Width Modulation (PWM) signal to select to power the DALI at a selected current value between the zero current value and the maximum current value. The powered device includes a buck converter that receives a reference current based on the PWM signal to generate a fixed voltage corresponding to the selected current value provided to the DALI.

Drawings

FIG. 1 illustrates an exemplary powered device according to an exemplary embodiment.

Fig. 2 shows an exemplary implementation of a power-on device according to an exemplary embodiment.

FIG. 3 illustrates an exemplary method for dynamically selecting a current according to an exemplary embodiment.

Detailed Description

The exemplary embodiments may be further understood with reference to the following description and the related drawings, wherein like elements are provided with the same reference numerals. Example embodiments relate to devices, systems, and methods for dynamically selecting current settings for a Digital Addressable Lighting Interface (DALI) current source in an electronic device utilizing a DALI. The exemplary embodiments provide a compact method of selecting when to provide current and current settings to a DALI. Exemplary embodiments are directed to the following current sources: the current source may be configured to a different current setting than the primary side microprocessor while including only a minimal number of components. As will be described in detail below, the exemplary embodiments provide a mechanism to utilize a Pulse Width Modulated (PWM) signal across an isolation barrier, setting multiple configuration parameters using a single opto-isolator.

The exemplary embodiments are described with respect to particular circuit components interconnected within a power control mechanism of an electronic device. Example embodiments are also described with respect to these particular circuit components arranged in a particular configuration. However, the type and specific arrangement of the circuit components are for illustration purposes only. It is also within the scope of the exemplary embodiments to use different types of circuit components and different arrangements to achieve a substantially similar manner of dynamically selecting current settings across the isolator. In a first example, the load of the electronic device is described as a diode, such as a Light Emitting Diode (LED). However, the load may include any sub-component that draws power to activate the sub-component or stops drawing power to deactivate the sub-component. In a second example, an electronic device is described as including an isolator, such as an opto-isolator. However, the opto-isolator may be any isolator circuit component between the controller (e.g., microprocessor) and the DALI.

Exemplary embodiments are further described with respect to specific values associated with the powered device as a whole or various components of the powered device. These values may be optional current settings, for example. In another example, the values may be parameters of the PWM signal. However, these exemplary values relate to a particular implementation of the exemplary embodiments. Thus, any values used to describe the current setting selection mechanism according to the exemplary embodiments are for illustration purposes only, and other values may be used within the scope of the exemplary embodiments.

The illustrative embodiments provide a current setting selection mechanism that allows for selectively providing a current and a plurality of different current settings for the current to a DALI. With a single opto-isolator between the controller and the DALI, the controller can generate a corresponding signal that enables the current to be provided at a particular current setting. In this manner, a single opto-isolator can be used to turn the current source on or off and select the amount of current to be supplied.

FIG. 1 illustrates an exemplary powered device 100 according to an exemplary embodiment. The powered device 100 includes a power source 105, and the power source 105 supplies power to a load 115 through a DALI 110. The load 115 may be any type of component that draws power (e.g., an LED, a light bulb, an audio output component, etc.). The powered device 100 may include a controller 120 and an isolator 125, the controller 120 generating a signal to control whether current is provided to the load 115 through the DALI110, and the signal from the controller 120 crossing the isolator 125.

A current setting selection mechanism according to an exemplary embodiment may utilize the controller 120 to receive input or determine a current setting to be provided to the DALI 110. Based on the current setting, the controller 120 may generate an activation drive signal or a modulation drive signal that crosses the isolation barrier of the isolator 125 and causes a corresponding current having a value selected from the power source 105 to flow to the DALI110 and the load 115.

In a first operation, the controller 120 may be configured to switch the current to the DALI110 on or off. The controller 120 may generate an activation drive signal. When the activation drive signal is turned off, the current supply to the DALI110 is turned off (e.g., 0 mA). When the activation drive signal is on, the current supply to the DALI110 is on (e.g., a maximum current value, such as 110 mA).

In a second operation, according to an exemplary embodiment, the controller 120 may be configured to enable current to flow to the DALI110 at a selected value. The controller 120 may generate a modulated drive signal. When the current setting to be used is not 0 or the maximum current, the controller 120 may identify the current value of the current setting. The controller 120 may then determine a corresponding Pulse Width Modulation (PWM) signal that causes a current setting to be provided to the DALI 110. Thus, the controller 120 may utilize the modulated drive signal when the current to be provided to the DALI110 is a value between the off and on values (e.g., 0mA to the maximum current).

The modulated drive signal may be generated as a PWM signal such that the diode of the isolator 125 may be driven into conduction at a duty cycle and frequency corresponding to the selected PWM. The modulation drive signal enables current to be provided to the DALI110 at a current proportional to the PWM duty cycle of the isolator 125. According to an exemplary embodiment, a single isolator 125 may be used to set any current level of the DALI110 between 0mA and a predetermined maximum current by changing the duty cycle of the modulated drive signal from 0 to 100%, where the duty cycle is proportional to the current set point. Those skilled in the art will appreciate that the logic of the ratio may be reversed.

A powered device 100 is shown with components incorporated into a unitary electronic device. However, in another implementation, the components of powered device 100 may be at least partially separate from each other while having communication functionality, may be modular components (e.g., separate components connected to each other), may be incorporated into one or more devices, or a combination thereof. The powered device 100 may also utilize wired connections between components. However, one skilled in the art will appreciate that any manner of communication of signals, power, or other indications/commands may be used between the components of powered device 100. For example, a wired connection, a wireless connection, a network connection, or a combination thereof may be used.

Fig. 2 shows an exemplary implementation of a powering device 200 according to an exemplary embodiment. Powered device 200 may be a particular arrangement of powered device 100 of FIG. 1 according to an example embodiment. The implementation of the powered device 200 shown in FIG. 2 involves a current setting selection mechanism arranged in a particular manner, wherein the activation drive signal can switch the current on or off from zero current to a maximum current, or the modulation drive signal can switch the current on to a selected current between zero and the maximum current. Powered device 200 may include microprocessor 205, resistor 210, opto-isolator 215, voltage reference 220, resistor 225, resistor 230, capacitor 235, buck converter 240, negative DALI port 245, positive DALI port 250, and auxiliary power supply 255.

The implementation of powered device 200 in FIG. 2 may be any circuit implementation in which components are interconnected with one another to exchange signals and provide power along various circuit paths. These components may be included on one or more integrated circuits, on one or more printed circuit boards, or separately implemented as desired. The exemplary implementations of powered device 200 described herein relate to powered device 200 as a collection of circuit components. However, powered device 200 may also be implemented in a number of other ways.

In an implementation of powered device 200, the selection component may correspond to powered device 100. For example, the microprocessor 205 may correspond to the controller 120; optical isolator 215 may correspond to isolator 125; the auxiliary power supply 255 may correspond to the power supply 105; and the negative DALI port 245 and the positive DALI port 250 may be ports of DALI 110. Since the powered device 200 shows a specific implementation of the powered device 100, the components included in the powered device 200 are merely illustrative. For example, the isolator 125 being an opto-isolator 215 is merely illustrative, and any isolator circuit may be used. In another example, the controller 120 as the microprocessor 205 is merely illustrative, and any control circuit may be used.

According to an exemplary implementation of the powered device 200, the microprocessor 205 may be located on the primary side of the opto-isolator 215. In a first operation using the activation drive signal, the microprocessor 205 may generate a turn-on activation drive signal or a turn-off activation drive signal when the current provided to the DALI110 via the negative DALI port 245 and the positive DALI port 250 is 0 or a maximum current. The microprocessor 205 can use any activation drive signal to turn the opto-isolator 215 on or off, thereby generating zero or maximum current.

In a second operation with a modulated drive signal, the primary side isolated microprocessor 205 may generate a PWM signal that drives the diode of opto-isolator 215 via resistor 210. The output of opto-isolator 215 is connected to reference voltage 220(Vref) through current limiting resistor 225. The circuit path generates a square wave signal at the junction of the resistor 225 and the resistor 230 (e.g., assuming that the resistor 230 is very large compared to the resistor 225, such as exceeding a predetermined difference that generates the square wave signal). Resistor 230, along with capacitor 235, may function as a filter that switches the input of resistor 230 (e.g., the output of resistor 225) based on PWM. The input to resistor 230 may be approximately 0 or Vref based on the duty cycle. Resistor 230 and capacitor 235 may be used to average the PWM signal to generate a DC voltage reference for setting the current reference (Iref) of buck converter 240.

If PWM is defined as the voltage between the resistors 225, 230 (e.g., the inverse of the PWM of the microprocessor 205), the duty cycle of the PWM may be proportional to the current set point of the current source of the DALI 110. As shown, the current source of the DALI110 may be a buck converter 240. Since the input pin of the buck converter 240 is typically high impedance, no further buffering is required after the capacitor 235. The output of the buck converter 240 may be a fixed voltage to the negative DALI port 245.

Furthermore, since the current setting selection mechanism is a configuration set point for the current source of the DALI110, very fast reaction speeds are not required, as the current source may be fixed for a given installation and no dynamic reference current changes are required. Thus, the exemplary embodiment enables the current setting selection mechanism to freely select the PWM frequency, which is slow enough for opto-isolator 215 (which may be a standard opto-isolator without any modifications) to allow powered device 200 to have a very low cost. For example, a PWM frequency of 100Hz may be selected, which makes the rise and fall time delays of opto-isolator 215 negligible and allows for a fairly accurate current setting for Isource of buck converter 240. The microcontroller 205 may allow the PWM duty cycle to be accurate even though the frequency may not be as accurate.

FIG. 3 illustrates an exemplary method 300 for dynamically selecting a current according to an exemplary embodiment. The method 300 may involve the mechanisms of the exemplary embodiments as follows: wherein the microprocessor 205 is configured to determine when current is to be provided to the DALI interface 110 (e.g., including the DALI ports 245, 255) and the amount of current to be provided (e.g., from 0% to 100% of the available current). Method 300 will be described with reference to an implementation of powered device 100 of FIG. 1 and powered device 200 shown in FIG. 2. Substantially similar components of the exemplary implementations of powered device 100 and powered device 200 will be used interchangeably.

In 305, the powered device 100 determines a current to be provided to the DALI 110. As described above, the microcontroller 205 may receive an input corresponding to a current setting or determine a current setting to be used in the powered device 200. In 310, the powered device 100 determines whether to provide current to the DALI 110. If no current is provided to DALI110, the powered device 100 proceeds to 315 where the activation drive signal renders the diode of opto-isolator 215 non-conductive so that no current is provided to DALI 110. For example, the microprocessor 205 may generate an off activation drive signal. If current is to be provided to the DALI110, the powered device 100 proceeds to 320.

Whether to provide current to the DALI110 may also be based on the duty cycle of the powered device 100. For example, the duty cycle may indicate when a particular load 115 is receiving power. The duty cycle may also have a waveform, such as a square wave. Thus, based on a square wave, the current to be provided may be 0 or a selected current value. The selected current value may correspond to the input or determination performed in 305.

At 320, the powered device 100 determines whether the current to be provided is a maximum current (e.g., during a duty cycle). If the current to be provided is a maximum current, the powered device continues to 325 where the activation drive signal turns on the diode of opto-isolator 215, causing a maximum current to be provided to DALI 110. For example, the microprocessor 205 may generate a turn-on activation drive signal. If the current is set to a value between 0 and the maximum value, the powered device 100 continues to 330.

At 330, the powered device 100 determines that the modulated drive signal has a duty cycle and frequency corresponding to the selected current setting of the current to be provided to the DALI 110. For example, the microprocessor 205 may generate the modulated drive signal as a PWM signal. At 335, the PWM signal drives the diode of opto-isolator 215 to conduct at the corresponding duty cycle and frequency. Through the voltage reference 220, resistors 225, 230, capacitor 235, and buck converter 240, current may be provided to the DALI110 (e.g., via the negative DALI port 245) at a selected current value that is greater than 0 but less than the maximum current value.

Example embodiments provide devices, systems, and methods for dynamically selecting a current setting for power to be provided to a load via DALI. The current setting selection mechanism according to an exemplary embodiment performs a first operation of turning on or off a current to the DALI using an activation driving signal or a second operation of supplying a current to the DALI at a selected current value using a modulation driving signal. The modulated drive signal may be configured as a PWM having a duty cycle and frequency corresponding to the selected current value.

Those skilled in the art will appreciate that the above-described exemplary embodiments may be implemented in any suitable software or hardware configuration or combination thereof. In another example, the exemplary embodiments of the methods described above may be embodied as a computer program product comprising lines of code stored on a computer readable storage medium that are executable on a processor or microprocessor. For example, the storage medium may be a local or remote data store compatible with or formatted using any of the above-described operating systems for storage operations.

It will be apparent to those skilled in the art that various modifications can be made in the present disclosure without departing from the spirit or scope of the disclosure. Thus, it is intended that the present disclosure cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.