Resonant system controller and cycle-by-cycle predictive soft switching
Abstract
Disclosed techniques achieve soft-switching conditions by determining relative timing of switch states and events, and making recurring timing adjustments in successive cycles (i.e., cycle-by-cycle) to reduce timing errors that introduce switching losses. Timing adjustments provide a prediction of when an optimal soft-switching condition will exist during a subsequent cycle so that switch-actuation signals are provided, irrespective of inherent signaling and feedback delays, in advance of actually observing the condition, thereby subsequently changing a switching state within a desired threshold of the targeted soft-switching condition. Error in the prediction is observed and compensating corrections applied during the next cycle. The predictive nature of the timing corrections provides for rapid convergence on, and recurring refinement of, optimal timing parameters for multiple opposing switches that are coordinated so that the system (be it self- or forced-resonant circuitry) operates at high efficiency with minimal hard-switching or diode conduction losses.
Claims
exact text as granted — not AI-modified1 . A method of reducing switching losses during successive switch-mode power supply (SMPS) cycles of an SMPS comprising first and second electrically coupled switches that change switching states in response to, respectively, first and second signals, the method comprising:
generating during a first SMPS cycle the first signal at a first time to change a first switching state of the first switch; generating during the first SMPS cycle the second signal at a second time to change a second switching state of the second switch, the second time temporally displaced from the first time based on a timing parameter, the timing parameter being adjustable to coordinate the second switch changing its switching state when a soft-switching condition exists, the soft-switching condition characterized by a condition at which minimum hard-switching and diode conduction losses would result from the second switch changing its switching state; detecting a failure to adequately soft switch the second switch during the first SMPS cycle, the failure attributable to a timing error between when the second switch changes its switching state and when the soft-switching condition actually occurs for the first SMPS cycle; and in response to detecting the failure to adequately soft switch, adjusting, for a second SMPS cycle following the first SMPS cycle, the timing parameter to reduce during the second SMPS cycle the timing error between when the second switch changes its switching state and when the soft-switching condition actually occurs for the second SMPS cycle.
2 . The method of claim 1 , further comprising detecting the failure to adequately soft switch by receiving a signal indicating a hard switch of the second switch.
3 . The method of claim 1 , further comprising detecting the failure to adequately soft switch by detecting a delay between the second switch changing its switching state and a change in state of a switching node associated with the second switch.
4 . The method of claim 1 , further comprising adjusting the timing parameter by changing a pulse width of a resonant pulse corresponding to at least a portion of the first signal.
5 . The method of claim 1 , further comprising adjusting the timing parameter to facilitate a change in a deadtime between the first and second signals.
6 . The method of claim 1 , further comprising sensing a level of a voltage across the second switch to detect the failure to adequately soft switch.
7 . The method of claim 1 , further comprising sensing a level of a voltage at a switching node between the first and second switches to detect the failure to adequately soft switch.
8 . The method of claim 1 , in which the first and second switches are resonantly coupled to form a forced-resonant auxiliary resonant commutated pole (ARCP) system.
9 . The method of claim 1 , in which the first and second switches are coupled together at a node of a self-, forced-, or quasi-resonant system.
10 . The method of claim 1 , further comprising adjusting the timing parameter to maintain a substantially static period between a start of the first SMPS cycle and a desired value of a voltage at a switching node associated with the second switch.
11 . The method of claim 1 , further comprising adjusting the timing parameter to maintain a dynamic timing between a start of the first SMPS cycle and a desired value of a voltage at a switching node associated with the second switch.
12 . A resonant system controller (RSC) apparatus to reduce switching losses during successive switch-mode power supply (SMPS) cycles of an SMPS comprising first and second electrically coupled switches that change switching states in response to, respectively, first and second signals, the apparatus comprising:
a first control output to provide during a first SMPS cycle the first signal at a first time to change a first switching state of the first switch; a second control output to provide during the first SMPS cycle the second signal at a second time to change a second switching state of the second switch, the second time temporally displaced from the first time based on a timing parameter, the timing parameter being adjustable to coordinate the second switch changing its switching state when a soft-switching condition exists, the soft-switching condition characterized by a condition at which minimum hard-switching and diode conduction losses would result from the second switch changing its switching state; sensor feedback inputs to receive feedback signals including information for detecting a failure to adequately soft switch the second switch during the first SMPS cycle, the failure attributable to a timing error between when the second switch changes its switching state and when the soft-switching condition actually occurs for the first SMPS cycle; and circuitry configured to, in response to detecting the failure to adequately soft switch, adjust, for a second SMPS cycle following the first SMPS cycle, the timing parameter to reduce during the second SMPS cycle the timing error between when the second switch changes its switching state and when the soft-switching condition actually occurs for the second SMPS cycle.
13 . The apparatus of claim 12 , in which the information of the feedback signals includes timing information indicating a hard switch of the second switch.
14 . The apparatus of claim 13 , in which the timing information indicates a delay between the second switch changing its switching state and a change in state of a switching node associated with the second switch.
15 . The apparatus of claim 12 , in which the circuitry is further configured to adjust the timing parameter by changing a pulse width of a resonant pulse corresponding to at least a portion of the first signal.
16 . The apparatus of claim 12 , in which the circuitry is further configured to adjust the timing parameter to facilitate a change in a deadtime between the first and second signals.
17 . The apparatus of claim 12 , in which the information of the feedback signals includes a level of a voltage across the second switch.
18 . The apparatus of claim 12 , in which the information of the feedback signals includes a level of a voltage at a switching node between the first and second switches.
19 . The apparatus of claim 12 , in which the first and second switches are resonantly coupled to form a forced-resonant auxiliary resonant commutated pole (ARCP) system.
20 . The apparatus of claim 12 , in which the first and second switches are coupled together at a node of a self-resonant system.
21 . The apparatus of claim 12 , in which the circuitry is further configured to adjust the timing parameter to maintain a substantially static period between a start of the first SMPS cycle and a desired value of a voltage at a switching node associated with the second switch.
22 . The apparatus of claim 12 , in which the circuitry is further configured to adjust the timing parameter to maintain a dynamic timing between a start of the first SMPS cycle and a desired value of a voltage at a switching node associated with the second switch.
23 . A power supply system including the apparatus of claim 12 .Cited by (0)
No later patents cite this yet.
References (0)
No backward citations on record.