1. Introduction
The idea of a segmented LED light source (SLLS) and an appropriate LED driver for the color/tone regulated LED lamp considered in the scope of this work is an adaptable light source delivering necessary illuminance to the desired area of the illuminated surface. This LED module is formed of an SLLS with independently dimmable/switchable high-power LEDs on its separate branches. Independent driving of this amount of high-power LEDs is expensive and complicated. Therefore, a special multiple-channel LED driving approach (single-inductor multiple-output (SIMO) current source mode (CSM) LED driver) has been chosen to overcome the shortcomings mentioned above. The same multiple-output driving approach can be useful in many other LED applications such as horticultural lighting, controllable RGB ambient lighting, adjustable correlated color temperature (CCT) applications, matrix automotive lighting, etc. The approach itself can be considered as a multilevel current and light regulation method with fluent control between levels. The current regulation in the given application is not the primary goal (the primary goal is light regulation) and it is not explicit. However, having an isolating and parallelizing current commutating matrix and combining it with a set of simplified uncontrolled current sources with one controlled current source, it becomes possible to achieve more straightforward and explicit current regulation that widens the range of potential applications. For instance, it enables the use of a similar approach in battery applications—battery energy storage systems and chargers for larger or smaller all-electric vehicles, for example, personal mobility vehicles like wheelchairs.
The main idea of an LED driver for the SLLS considered in the scope of this paper is derived from the SIMO CSM driver which has been described most accurately in [
1]. The authors of [
1] describe the SIMO CSM driver as a multiple-output converter with current delivery functions suitable for current consumers such as LEDs and as an approach to simplify independent output controls in comparison with traditional voltage-source-mode (VSM) converters. These statements are validated by experimental results of the CSM single-inductor dual-output (SIDO) converter example. They also mention the necessity of using a current generator (constant current source) stage at the input of SIMO CSM as a drawback, as the most commonly used power supplies are voltage sources.
A similar idea of current source mode regulators has also been studied by the authors of articles [
2,
3,
4,
5] several years ago, as well as by other authors quite recently in [
6,
7,
8,
9,
10]. In [
1], as an advantage of the SIMO CSM driver, the simultaneous voltage step-up and step-down functions for multiple-output applications are mentioned. However, the simulations in [
2] show that the conditions for energy transfer exist only if the sum of the voltages across all energy transferring (output) capacitors (C21 and C2k in
Figure 1) does not exceed the input voltage when using CSM buck topology as an output stage for a SIMO converter.
In [
3,
4], the steady-state performance of three conventional VSM converters (buck, boost and buck–boost) in conjunction with LEDs has been compared with the performance of their corresponding CSM converters by several criteria (maximal dynamic gain, nonlinearity and span of usable duty cycle); in addition, static losses were estimated for CSM converters, and it was found that CSM converters are suitable for LED driving when taking into account all this criteria.
In [
5], a non-inverting buck–boost converter is considered as a combination of the constant current source (CSS) stage with the single current regulator (CR) stage, which in fact, is the initial configuration of SIMO CSM converters discussed above.
The essence of the idea stated by all these articles is that the current in each channel (individual LED or LED string) can be regulated in a simple way without the need for implementation of closed-loop regulation when using current regulators (CR). The single inductor L1 is used for constant current forming as a constant current source (CSS) for whole circuits, as shown in
Figure 1. Only this part of the circuit (single-inductor-based constant current source) needs to be equipped with closed loop regulation (current feedback). The alternative method for independent current regulation is using independent LED drivers (constant current sources equipped with closed-loop regulation) for each channel, which complicates the control system and increases the number of components and the cost of a circuit.
Additionally, in [
6,
7], a different combinations of CSM buck and boost topology output stages in an SIDO converter are derived, analyzed and summarized by the article authors. In [
8,
9], the complete set of 16 possible configurations of SIMO CSM converters with multiple outputs is summarized.
In [
10], an example of the practical usage of a three-output SIMO converter as an off-line converter is analyzed.
Usually, a configuration of multiple output converters with colored LEDs is considered for applications where precise color control during dimming is required and relatively low-power LEDs are used (in applications such as display backlighting) [
10,
11,
12,
13,
14,
15].
We are highlighting that our proposed driver configurations are the most appropriate for use with high-power and high-current LEDs in applications where absolutely precise color representation is not critical, but the most critical factor is a fluent transition between different color combinations. The applications where such a driver would be the most appropriate are white light with adjustable CCT (two colored LEDs) and horticultural lighting (two to four different color LEDs).
In contrast with the common inductorless representation of CR stages, we use inductors L21 … L2k to show the inherent current source nature of the current regulator, as shown in (
Figure 1).
SIMO CSM efficiency-related issues have been considered in several articles. Efficiency improvement using the adaptive current bus approach is proposed in [
16], and restriction with low-frequency pulse width modulation (PWM) dimming is described (however, this restriction could be under discussion).
Another article on SIMO CSM efficiency issues is [
17], with a proposal of soft switching. However, the analysis and discussion of the efficiency results are not presented in the paper.
The question is the impact on the efficiency of the whole driver of the presence of a series diode in the circuit of each individual channel of the driver, especially the in case of using high-power LEDs with high current rates (in the rate of several amperes). The proposed improvement of this issue is discussed further in one of the sections of the paper.
Also, there is lack of discussion on driving circuit implementation for SIMO CSM drivers in existing papers. As the number of controllable switches not referenced to the ground (negative node) or positive node is equal to n − 1, where n is the number of independent driver channels, isolated gate driving circuits or other special driving approaches may be required for proper MOSFET transistor driving. Thus, particular attention in this paper has been paid to this issue.
Another topic for discussion is CCS as the input for independent channel current regulators. For the initial investigation, a prototype with an MP24833 integrated circuit (IC)-based CCS was made, which is discussed in the following section. However, the different inductor current limiting/forming control strategies can be implemented using other ICs or control methods, which is another direction for further research.
So, the purpose of this paper is the practical validation of multiple output LED drivers with the simple control method described in the papers mentioned above. The prototype of the modified SIMO LED driver discussed in further sections of this paper has been prepared for the validation of the issues listed above. A detailed discussion is given in the following sections.
2. Implementation of Constant Current Source Based on Common Existing Solution
There are many possible LED driver implementation options. However, existing LED drivers mostly are based on switch mode power converters (SMPC) with closed current regulation circuits due to several advantages. The most valuable among them is high efficiency. Buck SMPC is the most commonly used candidate for these purposes. A common simplified buck SMPC-based constant current LED driver is shown in
Figure 2. An LED driver can be considered as a matching element between a voltage source and an electrical current consumer.
Current feedback is formed by the current sensor I_CS, which measures the actual current i_L flowing through choke L1, adder SUM, which gives an error signal (the difference between the actual i_L1 and set current I_set), and the control unit U11, which consists of a regulator and a pulse width modulator (PWM). According to the received error signal, it forms a control signal for transistor Q1. Since the current source without load theoretically can generate an infinitely high voltage on its nodes, the protection of the converter output is applied: an output voltage limiter based on comparator U12, which compares the voltage from the divider R1, R2 with the maximal set value.
Such a typical LED driver with minor modifications can serve a CSM source function. These minor modifications include the removal of the output capacitor C_LED and the output voltage limiter, which is formed by R1, R2 and U12 in
Figure 2, or increasing the value of the voltage limiter to the required level, which must be equal to the voltage drop value across all series-connected LEDs in all channels with a small margin.
For experimental validation, a modified EV24833-A-N-00A buck/boost configurable development kit based on MPS MP24833 LED driver IC [
18] was used in the scope of this work, as shown in
Figure 3. On this development board, the changes mentioned above have been made, thus achieving the desired behavior of the CCS: the removal of capacitor C5 and adjustment of the voltage divider R8, R9.
The approach considered in the scope of this paper (the modification of an existing LED driver to CCS and using it in combination with additional modified CRs stages) can be used for upgrading existing no-controllable LED lighting systems to adjustable light output systems with simplified control.
4. Implementation of Light Flux Regulators
To distinguish the previous discussed CR concept from the new modified CR stage with parallel controlled switches, we introduce the name “light flux regulator” (LR) for this whole combination as well as “current switch” (CS) for parallel controlled switches inside this regulator. The implementation of light flux regulators LR1 for each regulated channel is shown in
Figure 4a.
Each LR1 is constructed as a combination (series connection) of single current regulator CR1 and a chosen number of current switches CS1y, which are controllable switches Q31y connected in parallel with light-emitting diodes LED1y1 … LED1yz, where y is the numbering index for current switches, while z is the numbering index for LEDs. Current regulator CR1 consists of capacitor C21 connected in parallel with LED11 … LED1z, they are connected in series with an uncontrolled switch—diode VD21 (which in general, can also be a controllable switch). As mentioned previously, in comparison with the original CR circuit from [
1], we use inductors L21 … L2k to show the inherent current source nature of the current regulator as shown in
Figure 1 and in [
2]. Controllable power switch Q21 is connected in parallel with all these components. Q21 is controlled by a pulse width modulation PWM signal. The average current value
I_LED_CR1 of the CR1 branch of light diodes LED11 … LED1z depends on the value of the transistor Q21 control signal duty cycle
D_Q21 and the constant current value
I_L1, and is equal to [
3]:
but the current value
I_LED_CS1y of the CS1y branch of LED1y1 … LED1yz is either 0 or
I_L1, depending on the specified value of the control parameter and the corresponding transistor Q31y control signal duty cycle
D_Q31y.
As discussed above, the main aim for CR’s modification is efficiency improvement by modifying hardware parts as well as a light flux regulation control algorithm to bypass CR’s high-side diode over part of the regulation range with higher output power.
A simplified calculation for CR stage diode power loss and the efficiency curves were built for the bare CR stage and for the LR stage. The comparison is shown in
Figure 5.
It is seen from these graphs that there is better efficiency of the LR stage at a higher output power and worse results in a low power range in comparison with the bare CR stage because only the CR part operates in LR at low light outputs. To achieve better efficiency of the lamp, the light output control strategy for LR can be constructed in such a way that the CR part is involved only in fluent transitions between different brightness states.
6. Considerations on Control Circuit Implementation
The main topic of this article is the discussion of the practical implementation of the SIMO LED driver and possible solutions for existing non-controllable LED lamps, upgrading them to regulated light color lamps using this driver.
As discussed above, the standard LED driver with minor modifications can be reconfigured to CCS suitable for use as part of the SIMO driver. In this way, part of the existing non-controllable LED lamp can be used. The problem with the power supplies of existing non-controllable LED systems is an absence of low-voltage output suitable for the supply of control circuits of the proposed SIMO driver: single current source output is available. One or several LEDs in a separate unregulated branch (UB) of the segmented LED light source (SLLS) can be used for the extraction of suitable voltage for the control system block (CSB) of the proposed SIMO driver from this current source (LED driver). The discussed principle is shown in
Figure 7. Of course, this method leads to noticeable disadvantages: such a lamp will always produce a minimum luminous flux of a certain color light, specified by LEDs from the introduced UB of SLLS. However, the described approach of voltage extraction for the supply of control parts can be used in LED lighting applications, where this minimum output light drawback does not matter. This allows for the simplification of the lamp’s overall structure and for cost optimization.
LEDs in the unregulated LED branch LED0 … LED3 of SLLS function as a voltage stabilizer for both the microcontroller MCU1 at 3V0 and the isolated MOSFET drivers DRV_CR1 … DRV_CRk, DRV_CS11 … DRV_CSkn of power switches Q21 … Q2k, Q311 … Q3kn at 12V0. For the optimization of transistor driving circuits, the UB of a segmented LED light source can be split and located at the CCS’ both negative and positive nodes as well, and both type N-FET and type P-FET transistors can be used in this case.
8. Experimental Validation
For experimental validation, the prototype of the proposed modified SIMO driver was built by combining CCS based on an MP24833 LED driver IC (
Figure 3) and one LR stage. The LR for testing purposes was built on two separate stackable PCBs/boards, splitting the power part and control part (these PCBs/boards are shown in
Figure 9).
The LR stage (power part, which is shown in
Figure 9b) of the prototype is configured as the combination of one current regulator CR1 with four current switches, CS0 … CS3. For testing purposes, the most robust FET driving circuit configuration was selected for implementation in the prototype board: isolated gate drivers with an isolated supply for each driver.
As the control system, the core of the proposed LR RP2040 microcontroller was selected. However, it could be any other microcontroller with enough configurable GPIOs: for this prototype, one PWM output and four GPOIs. For testing purposes, two control parameter input methods were implemented: (1) by trimmer and MCU readings of its set value on ADC input and (2) by “increase”/“decrease” push-buttons. A board of the control parts of the prototype is shown in
Figure 9a.
The testing setup for the experimental validation of the proposed LR is shown in
Figure 9c. Summaries of the initial tests are given in
Figure 10 and
Figure 11.
The experimental validation of single LR stage luminous flux regulation is shown in
Figure 10. The measurements were made with an indirect method using a luxmeter at the central point below the LED module. Correspondence of the control signals to the illuminance at the center point below the LED module at 1.1 m distance is shown here. The tests were conducted with the quite old (still in good condition), white, high-power LEDs available in the laboratory: Seoul Semiconductor W724C0 LEDs. The V–A and A–lm curves of a single LED of the mentioned type are given in [
19]. The configuration of the module was made as shown in
Figure 4b, except for the number of CS stages (three stages). The placement of LEDs is close to each other, but not perfectly symmetrical. Thus, the deviation of the experimental points across a linear interpolation is seen in
Figure 10, close to the transition points when switching to the next CS combination state.
The assessment of the efficiency of the proposed system configuration is given in
Figure 11. The tests for all dimming options were performed in similar conditions to the LED module mentioned above, with the maximum output power approximately 50 W using eight LEDs in total. Input voltage in all conducted experiments was the same, 35 V. The data obtained using Newtons4th Ltd. (Leicester, UK) PPA5530 precision power analyzer were used for this experimental efficiency validation. It is seen here that the efficiency of the bare CCS part is noticeably better in comparison with the combination of CCS+CR, which is the price for using such a kind of SIMO driver in high-power applications. However, as can be seen from
Figure 11, some efficiency improvements can be achieved using the proposed configuration with light regulator stages.