Not Applicable
Not Applicable
Not Applicable
1. Field of the Invention
The present invention relates to DC-DC converters and, more specifically, to regulation control systems and methods for such converters.
2. Description of Related Art Including Information Disclosed Under 37 CFR 1.97 and 1.98
Driven by faster processors and various silicon chip speeds, the voltage required to power such chips is steadily declining. In the modern telecommunication networks, wireless communication systems, computing and data storage systems, various voltage levels (also called rails) are needed to power various processors, memory chips, application specific IC (ASIC) chips for the best performance. Also, the dc-dc converter power modules required to power the chips may need to be located as close to the chips as possible in order to provide fast load transient response. These non-isolated dc-dc converter modules are referred as Point-of-Loads (POLs).
Over the last two decades, the power electronics industry has managed to significantly improve the power conversion efficiency of the dc-dc converters and POLs thanks to new silicon devices, better ferrite core material, packaging design, and most importantly, the conversion system architecture—the distributed power architecture (see
A traditional distributed power architecture (DPA) block diagram is shown in
An isolated intermediate bus dc-dc converter (IBC) is inserted between the −48V bus and the point-of-load (POL) dc-dc converters to convert −48V to either regulated 12V or 9.6V or 5V low voltage bus or unregulated 12V, 9.6V or 5V bus since typical POLs operate from either 4.5V to 14V input range or 2.4V to 5.5V input range. The intermediate bus converter can be a fully regulated dc-dc converter or semi-regulated converter or an unregulated converter since the output voltage regulation can be done by various POL converters.
The non-isolated, but fully regulated POL converters then convert the bus voltage to even lower voltage rails to power various required loads such as microprocessors, digital signal processor (DSP), amplifiers, application specific IC chips (ASIC), serial communication devices, etc. Usually. POL converters will achieve the highest efficiency at lower end of input voltage range while the conversion efficiency of the intermediate bus converter (IBC) maximizes at higher output voltage such as 12V. A trade-off needs to be made to select the IBC output voltage in order to achieve the best system level efficiency.
In a modern switch-mode dc-dc converter, the pulse-width modulation technique is used to regulate the converter output voltage. In the case of a full bridge converter (see
From the power conversion efficiency point of view, the higher the duty cycle, the better the conversion efficiency. However, for a wide input voltage telecom power system, for example, the −48V bus voltage can vary from −36V to −75V (i.e. 2:1 ratio). Sometimes, it can be 18V to 75V or even wider. The wide range of the input voltage requires the transformer turns ratio to be chosen so that the converter maintains the regulation at minimum input voltage with some voltage margin for the converter internal impedance associated losses. As a result, the converter will have increased primary side current due to low transformer turns ratio and too much voltage available when the input voltage is at highest point. This applies very high voltage stress to the secondary side FETs so that higher voltage rated FETs need to be used (i.e. less efficiency) and requires the converter to operate at very small duty cycle in order to maintain the regulation for a given output voltage. The increased current in the primary winding and power switching FETs also leads to higher conduction and, greater switching losses. Each of these drawbacks causes the dc-dc converter to have lower overall conversion efficiency and requires greater effort to remove the heat that is generated.
In the case of narrow input voltage range applications such as computing and data storage systems, or when the −48V bus is well regulated and not required to have a battery back-up, the intermediate bus converter can be designed differently. Such IBCs can utilize optimal transformer turns ratios and can be operated at nearly fixed duty cycle while allowing the output voltage to vary as the input line voltage and/or output load changes. This is possible because the downstream POL converters can accept wide input voltage range, i.e. 4.5V to 14V, and provide their own regulation for the chip load. This unregulated IBC allows nearly continuous power flow from the input or primary side to the output or secondary side while maintaining the highest possible duty cycle and optimal transformer turns ratio, and hence, the lowest voltage rated secondary switching FETs and the highest conversion efficiency. The concept of fixed duty cycle isolation stages (sometimes referred to as “DC transformers”) combined with switching post regulators (or POLs) has been well known in the industry for decades.
Traditional isolated bus converter designs often include non-regulating isolated full bridge converters followed by several non-isolated post-regulators or non-isolated POLs converters. These full bridge dc-dc converters, such as that shown in
Another traditional dc-dc converter system design consists of an isolation/semi-regulated forward converter stage followed by several non-isolated post regulators or POLs. In this design the control circuit senses a voltage in the forward converter primary transformer winding circuit to provide a feedback control signal without bridging the primary/secondary isolation barrier. However, because the output voltage is not directly sensed, the output voltage drops as the load current increases due to the impedance of the dc-dc converter.
Although the duty cycle of the forward converter can be slightly adjusted by sensing the primary transformer winding circuit, the output voltage of the isolation stage is still subject to droop. If the input voltage range is relatively wide such as 36V to 75V, the output voltage can vary excessively depending on the main transformer turns ratio. Moreover, the resulting output could be so low at 36V input that it would NOT be suitable for high power application due to heavy current loss in the 12V (nominal) DC distribution bus (i.e., I2R loss).
Another known control scheme creates a quasi-regulated converter.
The most common method for using feedback control to tightly regulate converter output is by use of the sensed output voltage signal from the converter output side (or secondary side cross the primary secondary boundary when there is an isolation).
What is needed is a control scheme that senses the output voltage directly and, in a low-cost way, loosely regulates the output voltage to meet the POL load requirement. Furthermore, this new scheme should utilize a large transformer turns ratio (for instance, N≧4 for a 36V to 75V input and output>8.3V telecomm bus converter system or N≧5 for a 51V to 60V input and output>9.6V bus converter system) to achieve greater conversion efficiency by recognizing that a tightly regulated output voltage is NOT required for POL loads
A first embodiment of the present invention includes an isolated dc-dc converter device, the device comprising: a primary side circuit and a secondary side circuit, the primary side circuit accepting an input voltage, the secondary side circuit galvanically isolated from the primary side circuit by a transformer, the secondary side circuit for generating an output voltage determined by the duty cycle of the primary side circuit; and a flux-control device for varying the duty cycle of the primary side circuit based upon the volt-second of the transformer primary side windings in order to loosely regulate the output voltage.
Another embodiment includes a method, the method steps comprising: in a dc-dc converter device comprising a primary side circuit galvanically isolated from a secondary side circuit, the galvanic isolation provided by a transformer comprising at least one primary winding and at least one secondary winding, measuring the volt-second of the primary side winding of the transformer; and loosely regulating a voltage output of the secondary side circuit by altering the duty cycle of the primary side circuit based on the volt-second measurement.
The present invention will be more fully understood by reference to the following detailed description of the preferred embodiments of the present invention when read in conjunction with the accompanying drawings, wherein:
The above figures are provided for the purpose of illustration and description only, and are not intended to define the limits of the disclosed invention. Use of the same reference number in multiple figures is intended to designate the same or similar parts. Furthermore, when the terms “top,” “bottom,” “first,” “second,” “upper,” “lower,” “height,” “width,” “length,” “end,” “side,” “horizontal,” “vertical,” and similar terms are used herein, it should be understood that these terms have reference only to the structure shown in the drawing and are utilized only to facilitate describing the particular embodiment. The extension of the figures with respect to number, position, relationship, and dimensions of the parts to form the preferred embodiment will be explained or will be within the skill of the art after the following teachings of the present invention have been read and understood. (58,266).
Again,
When the primary switching devices Qa and Qd are turned off, the energy stored in the output inductor Lo is released. This forces the inductor current to freewheel via the output capacitor bank Co, the body diodes of the rectifying devices SR_ad and SR_bc, and the transformer secondary windings. By turning on SR _ad and SR_bc, the freewheeling current conduction loss are minimized since the voltage drops across the secondary side FETs SR_ad and SR_bc are much lower than the voltage forward drops of the FETs body diodes.
When the other diagonal primary switching pair devices Qb and Qc are turned on, the main transformer T1 is reset and the input power is delivered to the secondary side again. The secondary side controllable rectifier SR_bc is then turned on to achieve the synchronous rectification.
By varying the duty cycle of the primary switching pair devices, the energy flow from the input side (primary side) to the output side (secondary side) can be balanced and hence the output voltage. A small time delay between the primary switch pair Qa and Qd turn-off (or turn-on) and the other switch pair Qb and Qc turn-on (or turn-off) is required to prevent the shoot-thru current from the input bus via the top switch to the bottom switch of the primary FETs. The maximum duty cycle of the primary switches is limited to 50%. For the best efficiency and the input and output ripple cancellation, the duty cycle is preferably a 50%, i.e. no regulation against input line and output load variation.
The definition of the duty cycle for a pulse-width modulated (PWM) DC-to-DC converter circuitry is illustrated in
D=ton/Ts=ton ×fs Math (1)
For an un-regulated dc-dc converter, the switch turn-on time is fixed. It is not controlled based on any feedback measurement. Since the switching frequency is also fixed for the ease of design of the magnetic components and the noise filtering circuit, the switch duty cycle D is also fixed to approximately 50% for double ended converters such as half bridge and full bridge converters.
For a tightly regulated dc-dc converter, an output voltage sensing circuit is used to sense the output voltage. This sensing circuit then feeds back the sensed signal to an error amplifier, which compares this signal with the preset reference voltage so as to control the switch turn-on time. If the output voltage is below the desired preset reference voltage, an error signal is generated, which causes the controller to increase the switch turn-on time, ton, and hence to increase the switch duty cycle, D since fs is fixed. Alternatively, if the output voltage is higher than the desired voltage, a negative error signal will be generated to cause the controller to reduce the switch turn-on time, reducing D. In an ideal case, the output voltage transfer function of a full bridge converter can be written as follow:
Vo=2(ns/np)×(ton)×Vin×fs Math (2)
where np and ns are the number of turns of transformer T1, primary winding and secondary winding, respectively, and Vin is the input voltage. For a given design, np and ns are constants.
In the proposed control scheme of
A variation of the proposed scheme is illustrated from
The control scheme is further explained in
Another variation of this proposed new control scheme is shown in
This embodiment of the sensing circuitry consists of two resistors (R1 and R10), a Zener diode (CR1), and an optocoupler (U1), the optocoupler having a light emitter (U1_a) and a photosensor (U1_b) to optically isolate the primary side from the secondary side. Although an optocoupler secondary side circuit to primary side circuit (secondary-to-primary) signal coupling device is expressly depicted, other embodiments may utilize a linear isolator based on magnetic coupling technology, capacitive coupling, differential mode amplifier technology, or the like. As another example, it is possible to utilize commercially available isolators including, but not limited to, the Texas Instruments ISO7421E or Analog Devices ADuM3210 device as a signal coupling device. Such signal coupling devices are within the scope of the claims herein.
In yet another embodiment a voltage controlled oscillator (VCO) is used to convert a voltage signal to a digital pulse train. In this embodiment, a higher sensed voltage causes the pulse train frequency to increase (i.e higher frequency). An optocoupler or other signal coupling device may then be used to transfer the digital pulse trains across the primary/secondary boundary. In this embodiment the digital controller senses the pulse train and, based upon the pulse train, calculates the frequency and converts it to a reflected voltage signal.
Referring again to
As depicted, this embodiment senses the output voltage via the zener diode (CR1) and resistor (R10) combination circuit, and feeds back the sensed voltage to the primary (controller) side using an optocoupler device (U1). A quasi-linear voltage curve, which is proportional to the output voltages, can be obtained at the controller side as shown in
As shown on the graph, with a 6.8V zener diode plus a 4K resistor in series with the optocoupler and an output voltage regulation set-point close to 9.6V, the sensed voltage (Vsensed) at the controller side (optocoupler transistor side) is approximately 1V. This analog voltage representing the output voltage reading (approximately 9.6V) is provided to the digital (or analog) primary controller. A digital controller (microcontroller or microprocessor) utilizes an analog-to-digital converter, which converts the analog signal to the digital signal (bits). A digital PI (proportion and Integration) or PID (proportion, integration, and differentiation) control loop or algorithm may then (based upon the Vsensed measure) be used to regulate the secondary side output voltage against the variations of the input voltage and load current within a specific desired band. In another embodiment, this sensed voltage signal (Vsensed) is also used for output over-voltage protection whenever the sensed voltage is higher than a pre-defined value, e.g. 2.6V, by causing a shutdown of the converter switching. The dynamic performance of the output voltage against the line and load change depends largely on the digital control loop design and scheme used for a given switching frequency, power train design, and the output capacitance. Similarly, in another embodiment utilizing an analog controller, the controller utilizes a high gain or integrating amplifier and PWM controller to control Vsensed to similar effect.
The typical line regulation characteristics of the proposed loosely regulated control scheme from a 9.6V output, 450W converter is shown on the graph of output voltage (Vout) with respect to input voltage (Vin) depicted in
The typical output voltage regulation characteristics of the present embodiment of the proposed loosely regulated feedback control converter is further depicted in
Vo=(2D)×Vin×(ns/np) Math (3)
where D is the switching duty cycle, Vin is the input voltage, and ns and np are the main transformer secondary and primary number of turns, respectively. For given ns, np, and D values, the output voltage reaches the maximum at Vin_max. With the addition of CR1 and the Zener voltage set at Vz1, the output voltage will reach the predetermined value at Vo=Vz1. In the first case (1412), the converter loosely regulates using a zener diode (CR1) with a voltage rating (Vz1) that equals the sensed output voltage (Vo_sns=Vz1).
Before Vo_sns (or Vsensed) reaches Vz1, the regulation loop commands maximum duty cycle to deliver the maximum possible power to the output to raise the output voltage. Once Vo_sns reaches the predefined set-point, Vz1, the duty cycle of the converter starts to pull back from the maximum in order to regulate the output voltage at around 9.6V. As the input voltage continues to climb, the output voltage tends to increase as well for a given converter duty cycle, as does the feedback signal, Vo_sns. A higher Vo_sns signal, representing higher output voltage, allows the controller to further reduce the duty cycle to balance the power flow from the primary side to the secondary side so as to regulate the output voltage. As shown in
In another embodiment, shown as a second case in
Those skilled in the art will recognize that the controller may also be placed on the secondary side, eliminating the isolation device in the feedback loop. Lower cost components and the loose regulation approach described could still be used in this alternate embodiment, with further simplification. However, additional circuitry would be needed for isolation of primary drive signals and providing secondary bias power.
A described previously, a benefit of the present embodiment over traditional designs is that the present embodiment can utilize a large transformer turns ratio converter to maximize converter efficiency. For example, for a 36V to 75V input and 12V output system a 5:1 transformer turns ratio can be utilized instead of a standard 3:1 transformer turns ratio taking the advantage of POL load. This is beneficial because, in order to tightly regulate the output voltage at 12V, the transformer turns ratio must be chosen based on the minimum input voltage (i.e., 36V as in the present example). A 3:1 turns ratio results in a 12V maximum possible voltage at Vin=36V (without considering the voltage drop due to the internal impedance of the converter with the load current flowing). This relatively low turns ratio results in higher primary side current for a given load current, resulting in higher conduction loss and switching loss associated with the primary side FETs and higher conduction loss associated with the transformer primary winding. A low transformer turns-ratio also creates higher voltage stress on the secondary side synchronous rectifiers for a given maximum source voltage. This higher voltage stress requires switching devices having a higher voltage rating, which, consequently, results in the switching devices having a higher on-state resistance and slower body diode reverse recovery characteristics leading to higher synchronous rectifier conduction and switching losses.
On the other hand, for a loosely regulated dc-dc converter as in the present embodiment, a larger transformer turns ratio such as 5:1 can be utilized for a 36V to 75 Vin, and 10.8V nominal output system since the typical downstream POLs can tolerate a wide input voltage range. A 5:1 transformer turns ratio leads to smaller primary side current so that the primary side switching device and transformer primary winding have lower power losses. The required voltage rating of the synchronous rectifiers is also lower for a given maximum input source voltage. Thus, while it is possible to utilize a turns-ratio of N≧4 for a 36V to 75V input and output>8.3V telecomm bus converter system, it is possible to utilize a turns-ratio of N≧5 for a 51V to 60V input and output>9.6V bus converter system.
The present embodiment provides continuous feedback to allow the primary to control the output voltage toward a predefined value, even when the input voltage is low. For example, if output cannot reach pre-defined set point (due to low input voltage), the control loop commands the maximum possible duty cycle as it seeks to drive the output voltage toward the predefined set point. When input voltage returns to an intermediate value (input line transient or step change), the output voltage increases in turn. The output voltage increase causes the sensing circuit to generate and feedback a voltage signal proportional to the output voltage to cause the primary controller to readjust the duty cycle such that the output voltage is driven to the desired predefined value. The high duty cycle operation during low input source voltage range in the present embodiment also allows efficient use of the transformer, which results in lower input and output ripple and, consequently, reduced downstream filtering device requirements. The operation of this embodiment does not change regulation mode based on the source voltage range like traditional converter designs previously discussed. Since no operation or regulation mode change is required, the possibility of erratic behavior or transients when switching control modes is avoided. The operation mode change can often generate an unwanted audible noise.
The loosely regulated feedback control scheme of the present embodiment also senses the output voltage directly and regulates the output voltage against both the input source and output load variations. As previously stated, the output voltage feedback control loop is present and active at all times, even if the converter output cannot reach the target voltage at some operating conditions. Even if the control loop may command the maximum possible duty cycle at low input source voltage, it can also still automatically regulate the duty cycle downward to improve the load transient performance of the dc-dc converter during a load-dump condition. Otherwise, if such regulating actions were not provided, the output voltage would swing higher during a load-dump, which commonly occurs with non-regulated intermediate bus converter and/or semi-regulated bus converter designs where the switching duty cycle is either fixed or changed slightly solely based on the source voltage and/or the primary winding signal. During the load dump, the input source voltage is fixed, as is the duty cycle of the semi-regulated converter or the quasi-regulated converter, An example is shown in
An embodiment of a simplified control software flow diagram is presented in
The feedback voltage Vo_f is digitized and then compared with the calculated Vz. If Vo_f<Vz, then the duty cycle is controlled in a high duty cycle mode for the front-end configuration (i.e., full bridge or half bridge). If Vo_f is greater than Vz, then the difference voltage is determined and checked against another threshold, ΔV. If the difference is below this threshold, then adaptive adjustable regulation of the duty cycle is performed as appropriate. If, however, the difference is greater than ΔV, non-linear adjustment of the duty cycle can be employed by the controller device to minimize overshoot of the output voltage.
In this embodiment, the pre-calculated and tabulated duty cycles (look-up table method) based on the optimal load and line transient responses may be stored in the memory to minimize real-time calculation latencies. The correct duty cycle for each switching is then determined by the feedback voltage and/or the error voltage.
Transformer flux is directly related to many items including transformer characteristics including, but not limited to, number of turns, core geometry, as well as the operating conditions including, but not limited to, voltage applied and time. If transformer flux level becomes too high, the transformer may saturate causing very high current and damage to the module. Even if peak flux is not too high, if the change in flux is high, transformer core losses increase, potentially leading to overheating of the device.
Volt-second monitoring allows collection of information about transformer flux level because many of the other parameters, including transformer turns ratio that impact the flux level are fixed parameters once the hardware has been selected. Volt-second monitoring provides a means for dealing with these fixed parameters.
Traditional power module designs include a control loop that gives relatively tight output voltage regulation during operation. However, many load types such as downstream power modules or fans may not require such precise regulation of the output voltage. In such a case the power module may be controlled simply by monitoring the transformer volt seconds to ensure that that the transformer flux is operating in the safe operating area.
In the example schematic of
Those of ordinary skill in the art will appreciate that the previously described embodiments of the proposed loosely regulated feedback control scheme and the circuitry implementation for isolated intermediate bus converter (IBC) to achieve the best conversion efficiency while maintaining reasonably good output voltage regulation band is for illustrative purposes only and other embodiments thereof are well within the scope and spirit of the present invention. Although the present invention has been described in detail, those skilled in the art should understand that they can make various modifications, changes, substitutions and alterations to the embodiments herein without departing from the spirit and scope of the invention in its broadest form.
The same operation principle can be applied to the other dc-dc converter circuits with very minor design changes. Those of ordinary skill in the art will appreciate that the same control scheme can be extended easily to the half bridge converter, push-pull converter, and other double-ended converter circuits without deviation from the spirit and scope of the inventive concepts proposed herein.
Likewise, the techniques described here can be further extended to single ended circuits, such as forward, flyback and others, with various transformer reset methods including resonant or active clamp. In this case, the maximum duty cycle will be determined by the topology, component selection, and transformer reset scheme, and may exceed 50%. However, the loose regulation techniques described herein may still be applied, with similar benefits.
The scope of the invention is established by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Further, the recitation of method steps does not denote a particular sequence for execution of the steps. Such method steps may therefore be performed in a sequence other than that recited unless the particular claim expressly states otherwise.
This application is a continuation application of nonprovisional patent application Ser. No. 13/070,959, entitled “Loosely Regulated Feedback Control for High Efficiency Isolated DC-DC Converters,” filed Mar. 24, 2011, and claims the benefit of provisional patent Application No. 61/411,672, titled “Adaptive Adjustable Regulation Control for High Efficiency Isolated DC-DC Converters,” filed Nov. 9, 2010.
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Number | Date | Country | |
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20120113687 A1 | May 2012 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 13070959 | Mar 2011 | US |
Child | 13293022 | US |