Patent Grant
9705325
This disclosure relates to power supply systems, and more particularly, to circuitry and methodology for controlling switching regulators to balance power or current drawn from multiple power supply inputs.
Devices having multiple power supply inputs may balance current drawn from these inputs to draw maximum power from all supplies without overloading individual inputs. Typically, the current balancing is performed using either resistive ballasting or active balancing.
Resistive ballasting involves adding series resistance to each input. As the current draw on one input increases, the voltage drop across the resistance on that input increases proportionally, decreasing the voltage available to the device from that input and causing it to draw more current from the other inputs. However, resistive ballasting tends to waste power in the resistors, especially when two input voltages are significantly different from each other.
Active balancing typically involves inserting a resistor in series with each input and measuring the current in each input across this resistor. The resulting signals are used to actively adjust individual regulators attached to each input to increase or decrease their percentage of the total current draw. This technique typically improves efficiency over the resistor ballasting scheme, but it is complicated and typically involves a large amount of specialized circuitry.
Therefore, it would be desirable to develop simple and efficient techniques for balancing power or current draw from multiple power supply inputs.
The present disclosure offers novel techniques for balancing power or current drawn from multiple power supply inputs.
In accordance with one aspect of the disclosure, a power supply circuit having multiple power supply inputs includes multiple switching circuits coupled to the respective power supply inputs, at least one inductive component associated with the switching circuits, and control circuitry for controlling the switching circuits so as to limit current in the inductive component in each switching cycle to a current value common to all switching circuits.
In particular, the control circuitry may control the switching circuits so as to limit the current in the associated inductive component in each switching cycle to a common peak current value.
Alternatively, the control circuitry may control the switching circuits so as to limit the current in the associated inductive component in each switching cycle to a common average current value.
As a result, the control circuitry may balance power or current drawn from each of the power supply inputs.
The inductive component may include a transformer. For example, a separate transformer may be provided for each of the switching circuits. Alternatively, a common transformer may be shared by the switching circuits.
In accordance with another aspect of the disclosure, the inductive component may include an inductor, which may be associated with each of the switching circuits.
Each of the switching circuits may comprise a switching regulator. For example, the switching regulators may have a flyback configuration. Alternatively, the switching regulators may have a buck configuration, a boost configuration, or a buck/boost configuration. Also, the switching regulators may be implemented as forward converters.
In accordance with an embodiment of the disclosure, the control circuitry may include comparator circuitry for comparing a value corresponding to current in each of the switching circuits with a preset threshold value common to all switching circuits. The preset threshold value may be selected to limit current in the inductive component associated with the switching circuits.
Further, the control circuitry may include logic circuitry responsive to an output of the comparator circuitry and controlled by a clock signal common to all switching circuits for producing multiple control signals for controlling the respective switching circuits.
The comparator circuitry may include multiple comparators corresponding to the respective switching circuits, and the logic circuitry may include multiple logic circuits responsive to the respective comparators for controlling switching of the respective switching circuits.
Alternatively, the comparator circuitry may include a single comparator for comparing a current value common to all of the switching circuits with the threshold value, and a logic circuit responsive to an output of the comparator for producing multiple control signals for controlling switching of the respective switching circuits.
The logic circuitry may produce interleaving control signals so as to turn on only one of the switching circuits at a time.
To limit the current in the transformer in each switching cycle to a common average current value, the control circuitry may further include an integrator responsive to current in each of the switching circuits for providing the comparator circuitry with a current value integrated over a switching cycle.
In accordance with another embodiment of the present disclosure, the control circuitry for controlling switching regulators operating in a buck mode may include differential-to-single-ended converters for converting differential signals sensed at the power supply inputs to single-ended signals. Comparators may compare the single-ended signals with a common threshold value selected to limit current in the inductive component. In response to outputs of the comparators, pulse-width-modulation circuits may control switching of the switching regulators.
In accordance with a further embodiment of the disclosure, the control circuitry for controlling the switching regulators operating in a boost mode may include comparators for comparing signals sensed at the power supply inputs with a common threshold value selected to limit current in the inductive component. Pulse-width-modulation circuits responsive to outputs of the comparators may control switching of the switching regulators.
The circuit of the present disclosure may support various arrangements of power supply inputs, including power supply inputs that share a common ground, power supply inputs that share a common power supply and use separate grounds, or power supply inputs electrically isolated from each other.
The switching circuits may be connected to provide a single power supply output or multiple power supply outputs.
In accordance with a further aspect of the disclosure, the power supply circuit of the present disclosure may be incorporated into a system for supplying power to a powered device over a communication link, such as Ethernet cabling, having a first wire set and a second wire set. The power supply circuit may balance signals supplied to the powered device from the first and second wire sets.
In accordance with one method of the present disclosure, the following steps are carried out to balance current drawn from multiple power supply inputs:
Each of the switching circuits may be turned off when a respective signal value reaches the preset threshold value.
Additional advantages and aspects of the disclosure will become readily apparent to those skilled in the art from the following detailed description, wherein embodiments of the present disclosure are shown and described, simply by way of illustration of the best mode contemplated for practicing the present disclosure. As will be described, the disclosure is capable of other and different embodiments, and its several details are susceptible of modification in various obvious respects, all without departing from the spirit of the disclosure. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as limitative.
The following detailed description of the embodiments of the present disclosure can best be understood when read in conjunction with the following drawings, in which the features are not necessarily drawn to scale but rather are drawn as to best illustrate the pertinent features, wherein:
Although the present disclosure uses the example of balancing current or power in a Power over Ethernet (PoE) environment, one skilled in the art would realize that the disclosed circuitries and methodologies are applicable to any system that draws power from two or more inputs.
Over the years, Ethernet has become the most commonly used method for local area networking. The IEEE 802.3 group, the originator of the Ethernet standard, has developed an extension to the standard, known as IEEE 802.3af, that defines supplying power over Ethernet cabling. The IEEE 802.3af standard describes a Power over Ethernet (PoE) system that involves delivering power over unshielded twisted-pair wiring from a Power Sourcing Equipment (PSE) to a Powered Device (PD) located at opposite sides of a link. Traditionally, network devices such as IP phones, wireless LAN access points, personal computers and Web cameras have required two connections: one to a LAN and another to a power supply system. The PoE system eliminates the need for additional outlets and wiring to supply power to network devices. Instead, power is supplied over Ethernet cabling used for data transmission.
The PSE 12 may interact with each PD 14 in accordance with the IEEE 802.3af standard. In particular, the PSE 12 and the PD 14 participate in the PD detection procedure, during which the PSE 12 probes a link to detect the PD. If a PD is detected, the PSE 12 checks the PD detection signature to determine whether it is valid or non-valid. The valid and non-valid detection signatures are defined in the IEEE 802.3af standard. While the valid PD detection signature indicates that the PD is in a state where it will accept power, the non-valid PD detection signature indicates that the PD will not accept power.
If the signature is valid, the PD has an option of presenting a classification signature to the PSE to indicate how much power it will draw when powered up. For example, a PD may be classified as class 0 to class 4. Based on the determined class of the PD, the PSE applies the required power to the PD.
A 802.3af standard PoE system supports transferring power only over two pairs of conductors, either over the data pairs 16 and 18 or over the spare pairs 20 and 22. However, due to the resistance and associated heating of the Ethernet cabling system, only a limited amount of power may be delivered over 2 pairs of conductors.
To provide more power to a PD, it would be desirable to use more wires in the Ethernet cable. In particular, power transferred from the PSE 12 to the PD 14 may be applied to both data and spare pairs of conductors of the same Ethernet link segment simultaneously to reduce the cable system resistance. As a result, the PSE 12 may be enabled to support high-power PDs requiring more power than available in accordance with the 802.3af standard. For example, a 48V DC voltage may be simultaneously applied from the PSE 12 to the data pairs 16 and 18, and the spare pairs 20 and 22 provided within an Ethernet link segment between the PSE 12 and the PD 14.
The balancing circuitry 100 includes a switching regulator (SR) 102 for each power supply input, and associated circuitry operating together with the switching regulators 102 to balance power or circuit drawn from the power supply inputs. For example,
Each of the switching regulators 102 may have a flyback configuration that enables generation of an output DC voltage less than or greater than an input DC voltage. As well known to one skilled in the art of switching regulators, a flyback switching regulator may provide a single output DC voltage, as well as multiple output DC voltages. Moreover, the switching regulators 102 may operate in a continuous mode as well as in a discontinuous mode.
Alternatively, each switching regulator 102 may be arranged in a buck configuration to reduce an input DC voltage to a lower output DC voltage, in a boost configuration to provide an output DC voltage higher than an input DC voltage, or in a buck/boost configuration to generate an output DC voltage opposite in polarity with respect to an input DC voltage. Further, each of the switching regulators 102 may be implemented as a forward DC-DC converter that directly transfers energy from the power supply input to the load during the on-time of the power switch.
Although the balancing circuitry 100 in
Moreover, the balancing circuitry of the present disclosure may be configured to draw equal current or power from each of the power supply inputs. Alternatively, any desired ratio may be set for amounts of current or power drawn from different power supply inputs.
For example,
In particular, the switching regulator associated with the input VIN1 includes a transformer 502, a MOSFET switch 504 and a diode 506; and the switching regulator associated with the input VIN2 includes a transformer 512, a MOSFET switch 514 and a diode 516. Outputs of the switching regulators are tied together to form a single output voltage Vout.
Sense resistors 520 and 522 are respectively connected to the electrodes of the MOSFET transistors 504 and 514. Comparators 524 and 526 are respectively connected to the sense resistors 520 and 522 to compare voltages corresponding to the current values in the sense resistors 520 and 522 with a common preset threshold value TH established to limit current in the transformers 502 and 512.
The R-inputs of SR flip-flop circuits 528 and 530 are respectively connected to the outputs of the comparators 524 and 526. The S-inputs of these SR flip-flop circuits are supplied with a common clock signal CLK. Output signal A of the circuit 528 is supplied to the gate of the MOSFET switch 504 to control switching of the switching regulator associated with the input VIN1, whereas output signal B of the circuit 530 is provided to the gate of the MOSFET switch 514 to control switching of the switching regulator associated with the input VIN2.
Each of the switching regulators is configured to turn on at a predetermined time, and then to turn off when the current in the respective sense resistor reaches a preset limit defined by the threshold value, which is the same for both regulators. When each regulator reaches this current limit, the energy stored in its transformer will be ½ LI2, where L is the inductance of the transformer, and I is a value of the current in the transformer. Hence, the energy stored in each transformer will be equal to a value independent of the input voltage. This energy is then transferred to the output during the time when the respective switch is off.
If one of the regulators is driven from a higher voltage, it will reach its preset limit sooner and operate at a lower duty cycle. As long as each regulator is running at the same clock frequency and the current limits are set to the same value, the energy consumed per switching cycle by each regulator will be the same, and integrated over time, equal power will be drawn from each input.
In particular, the switching regulator associated with the input VIN1 includes a transformer 602, a MOSFET switch 604 and a diode 606; and the switching regulator associated with the input VIN2 includes a transformer 612, a MOSFET switch 614 and a diode 616. Outputs of the switching regulators are tied together to form a single output voltage Vout.
Sense resistors 620 and 622 are respectively connected to the electrodes of the MOSFET transistors 604 and 614. Integrating circuits 624 and 626 are respectfully connected to the sense resistors 620 and 622 to integrate the respective current readings over complete switching cycles of the respective regulators. Comparators 628 and 630 are respectively connected to the integrating circuits 624 and 626 to compare voltages corresponding to the average current values produced by the respective integrating circuits with a common preset threshold value TH established to limit current in the transformers 602 and 612.
The R-inputs of SR flip-flop circuits 632 and 634 are respectively connected to the outputs of the comparators 628 and 630. The S-inputs of the SR flip-flop circuits are supplied with a common clock signal CLK. The output signal A of the circuit 632 is supplied to the gate of the MOSFET switch 604 to control switching of the switching regulator associated with the input VIN1, whereas the output signal B of the circuit 634 is provided to the gate of the MOSFET switch 614 to control switching of the switching regulator associated with the input VIN2.
Each of the switching regulators is configured to turn on at a predetermined time, and then to turn off when the average current produced by the respective integrating circuit reaches a preset limit defined by the threshold value common for both regulators. Therefore, the current drawn over the complete switching cycle from each of the two inputs will be forced to be equal.
In particular, the switching regulator associated with the input VIN1 includes a transformer 702, a MOSFET switch 704 and a diode 706; and the switching regulator associated with the input VIN2 includes a transformer 712, a MOSFET switch 714 and a diode 716. Outputs of the switching regulators are tied together to form a single output voltage Vout.
A sense resistor 720 is connected to respective electrodes of the MOSFET transistors 704 and 714. A comparator 722 is connected to the sense resistor 720 to compare the voltage corresponding to the current in the sense resistor 720 with a preset threshold value TH established to limit current in the transformers 702 and 712. The R input of an SR flip-flop circuit 724 is connected to the output of the comparator 722, whereas the S input is supplied with a clock signal CLK.
The output signal of the SR flip-flop circuit 724 is supplied to a logic circuit that produces interleaving pulse signals A and B for controlling the MOSFET switches 704 and 714, respectively. In particular, the output of the SR flip-flop circuit 724 is connected to a clock input of a T flip-flop circuit 726 and to first inputs of AND gates 728 and 730. Second inputs of the AND gates 728 and 730 are respectively connected to non-inverting and inverting outputs of the T flip-flop circuit 726. As a result, the AND gates 728 and 730 produce interleaving control signals A and B for controlling the MOSFET switches 704 and 714, respectively.
Due to the interleaving control technique implemented by the circuitry 700, the switching regulators associated with inputs VIN1 and VIN2 are switched in turn. Therefore, only one of the switching regulators is active at any given time period. A similar interleaving control technique may be used to control switching regulators in
Sense resistors 810 and 812 are respectively connected to the MOSFET switches 804 and 806. Comparators 814 and 816 are respectively coupled to the sense resistors 810 and 812 to compare voltages corresponding to the current values in the sense resistors 810 and 812 with a common preset threshold value TH established to limit current in the transformer 802. The output signals of the comparators 814 and 816, together with a common clock signal CLK, are supplied to interleaving control circuitry 818 to produce interleaving control signals A and B for controlling the MOSFET switches 804 and 806, respectively. The interleaving control circuitry 818 may be configured similarly to the control circuit in
In accordance with an exemplary embodiment shown in
Sense resistors 926, 928 and 930 are respectively connected to the electrodes of the MOSFET transistors 904, 914 and 9244. Comparators 932, 934 and 936 are respectively connected to the sense resistors 926, 928 and 930 to compare voltages corresponding to the current values in the respective sense resistors with a common preset threshold value TH established to limit current in the transformers 902, 912 and 922.
The R-inputs of SR flip-flop circuits 938, 940 and 942 are respectively connected to the outputs of the comparators 932, 934 and 936. The S-inputs of the SR flip-flop circuits are supplied with a common clock signal CLK. The output signal A of the circuit 938 is supplied to the gate of the MOSFET switch 904 to control switching of the switching regulator associated with the input VIN1, the output signal B of the circuit 940 is provided to the gate of the MOSFET switch 914 to control switching of the switching regulator associated with the input VIN2, and the output signal C of the circuit 942 is supplied to the gate of the MOSFET switch 924 to control switching of the switching regulator associated with the input VIN3.
Similarly to the circuitry in
Sense resistors 1016 and 1018 are respectively connected between the power supply inputs VIN1 and VIN2 and electrodes of the MOSFETs 1002 and 1004. Differential-to-single-ended converters 1020 and 1022 are respectively coupled across the sense resistors 1016 and 1018 to convert differential signals produced across the resistors 1016 and 1018 into single-ended signals. Comparators 1024 and 1026 compare the respective single-ended signals with a common threshold value TH established to limit current in the inductors L1 and L2.
The output of the comparator 1024 feeds a pulse-width modulation (PWM) circuit 1028 that produces a PWM signal for driving the gate of the MOSFET 1002 to control switching of the switching regulator associated with the input VIN1. The output signal of the comparator 1026 is supplied to a PWM circuit 1030 that produces a PWM signal for driving the gate of the MOSFET 1004 to control switching of the switching regulator associated with the input VIN2.
Hence, both switching regulators are controlled so as to limit the current in the inductors L1 and L2 to a common pick value defined by the threshold value TH. When each switching regulator reaches this current limit, the energy stored in its inductor will be ½ LI2, where L is the inductance of the inductor, and I is a value of the current in the inductor. Hence, the energy stored in each inductor will be equal to a value independent of the input voltage. This energy is then transferred to the output during the time when the respective switch is off.
If one of the switching regulators is driven from a higher voltage, it will reaches its preset limit sooner and operate at a lower duty cycle. As the energy consumed per switching cycle by each regulator will be the same, and integrated over time, equal power will be drawn from each input.
As one skilled in the art would realize, the balancing circuit 1000 may be modified to provide an equal current draw from each of the power supply inputs by integrating a signal produced across each of the sense resistors over the complete cycle of the regulators to define average current in each of the inductors L1 and L2. The average current may be limited to a common value in a manner similar to the technique disclosed in connection with
Sense resistors 1116 and 1118 are respectively connected to the electrodes of the MOSFET transistors 1102 and 1112. Comparators 1120 and 1122 are connected to the sense resistors 1116 and 1118, respectively, to compare voltages corresponding to the current values in the respective sense resistors with a common preset threshold value TH established to limit current in the inductors L1 and L2.
The output signals of comparators 1120 and 1122 respectively feed PWM circuits 1124 and 1126 that produce PWM signals for driving the gates of the MOSFETs 1102 and 1112, respectively. Hence, both switching regulators are controlled to limit the current in the respective inductors L1 and L2 to a level defined by the common threshold value TH. As a result, power drawn from each power supply input will be equal. One skilled in the art would realize that the balancing circuit 1100 may be modified to provide an equal current draw from each power supply input by limiting the average current in the inductors L1 and L2 integrated over the complete cycle of the regulators, to a common value in a manner similar to the technique disclosed in connection with
Although
The foregoing description illustrates and describes aspects of the present invention. Additionally, the disclosure shows and describes only preferred embodiments, but as aforementioned, it is to be understood that the invention is capable of use in various other combinations, modifications, and environments and is capable of changes or modifications within the scope of the inventive concept as expressed herein, commensurate with the above teachings, and/or the skill or knowledge of the relevant art.
The embodiments described hereinabove are further intended to explain best modes known of practicing the invention and to enable others skilled in the art to utilize the invention in such, or other, embodiments and with the various modifications required by the particular applications or uses of the invention.
Accordingly, the description is not intended to limit the invention to the form disclosed herein. Also, it is intended that the appended claims be construed to include alternative embodiments.
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