U.S. patent application number 17/109006 was filed with the patent office on 2021-03-18 for hybrid secondary-side regulation.
The applicant listed for this patent is DIALOG SEMICONDUCTOR INC.. Invention is credited to Yong LI, Wenduo LIU, Xiaoyan WANG, Cong ZHENG.
Application Number | 20210083586 17/109006 |
Document ID | / |
Family ID | 1000005248609 |
Filed Date | 2021-03-18 |
United States Patent
Application |
20210083586 |
Kind Code |
A1 |
LI; Yong ; et al. |
March 18, 2021 |
HYBRID SECONDARY-SIDE REGULATION
Abstract
A flyback converter control architecture is provided in which
primary-only feedback techniques are used to ensure smooth startup
and detection of fault conditions. During steady-state operation,
secondary-side regulation is employed. In addition, current limits
are monitored during steady-state operation using primary-only
feedback techniques to obviate the need for a secondary-side
current sense resistor.
Inventors: |
LI; Yong; (Campbell, CA)
; ZHENG; Cong; (Campbell, CA) ; WANG; Xiaoyan;
(Campbell, CA) ; LIU; Wenduo; (Campbell,
CA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
DIALOG SEMICONDUCTOR INC. |
Campbell |
CA |
US |
|
|
Family ID: |
1000005248609 |
Appl. No.: |
17/109006 |
Filed: |
December 1, 2020 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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16588854 |
Sep 30, 2019 |
10855188 |
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17109006 |
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16100934 |
Aug 10, 2018 |
10461646 |
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16588854 |
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PCT/US2018/013655 |
Jan 12, 2018 |
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16100934 |
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62445660 |
Jan 12, 2017 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H02J 7/00 20130101; H02M
3/33507 20130101; H02M 3/33592 20130101; H02M 1/32 20130101; Y02B
70/10 20130101; H02M 1/36 20130101; H02M 2001/0058 20130101 |
International
Class: |
H02M 3/335 20060101
H02M003/335 |
Claims
1. A method for a flyback converter, comprising: in a
secondary-side controller for the flyback converter, comparing an
output voltage for the flyback converter to a reference voltage to
determine a control voltage; transmitting the control voltage from
the secondary-side controller to a primary-side controller; in a
pulse width modulation mode of operation for the flyback converter,
processing the control voltage to determine a desired peak current
for a power switch; following a cycling on of the power switch in a
first power switch cycle, switching off the power switch responsive
to a current through the power switch equaling the desired peak
current; following the switching off of the power switch,
determining a transformer reset time from an auxiliary winding
voltage; and determining an average output current for the flyback
converter from the transformer reset time and the current through
the power switch.
2. The method of claim 1, further comprising: controlling a cycling
of the power switch during a subsequent second power switch cycle
independently of the control voltage responsive to the average
output current exceeding a current limit.
3. The method of claim 1, wherein comparing the output voltage for
flyback converter to the reference voltage comprises generating an
error voltage, the method further comprising filtering the error
voltage in a loop filter to produce the control voltage.
4. The method of claim 1, further comprising: from the primary-side
controller, transmitting an on and off status of the power switch
to the secondary-side controller.
5. The method of claim 4, further comprising: controlling a
synchronous rectifier switch to be off responsive to the on status
of the power switch.
6. The method of claim 1, further comprising: cycling a high side
switch following the cycling off of the power switch to discharge a
voltage across the power switch.
7. The method of claim 6, further comprising: from the primary-side
controller, transmitting an on and off status of the high side
switch to the secondary-side controller.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a divisional of U.S. patent application
Ser. No. 16/588,854, filed Sep. 30, 2019, issued as U.S. Pat. No.
10,855,188 on Dec. 1, 2020, which in turn is a divisional of U.S.
patent application Ser. No. 16/100,934, filed Aug. 10, 2018, issued
as U.S. Pat. No. 10,461,646 on Oct. 29, 2019, which in turn is a
continuation of International Patent Application No.
PCT/US2018/013655 filed on Jan. 12, 2018, which in turn claims the
benefit of U.S. Provisional Patent Application No. 62/445,660 filed
on Jan. 12, 2017, which applications are hereby incorporated by
reference herein in their entireties.
TECHNICAL FIELD
[0002] This application relates to switching power converters, and
more particularly to a hybrid secondary-side regulation scheme for
flyback converters.
BACKGROUND
[0003] Switching power converters offer higher efficiency as
compared to linear regulators. Although linear regulators are
relatively inexpensive, they regulate a lower output voltage from a
higher input voltage by simply burning the difference as heat. As a
result, a linear regulator typically burns more power than is
actually supplied to the load. In contrast, a switching power
converter regulates its output voltage by delivering relatively
small increments of energy through the cycling of a power switch.
The power switch in a switching power converter is either off or on
so that efficiency is markedly improved as compared to linear
regulators. Switching power converters such as a flyback converter
are thus typically used to charge the batteries for mobile
devices.
[0004] Not only are flyback converters efficient, their
transformers provide a safe isolation of the device being charged
from the AC mains. But this isolation leads to a regulation problem
since the output voltage (or output current) is delivered from the
secondary winding of the transformer whereas the power switch is
connected to the transformer's primary winding. A natural location
for a controller is thus on the primary side to regulate the output
power delivery by regulating the cycling of the power switch. But a
primary-side controller cannot simply read the output voltage
directly such as through a wire or lead because the isolation
between the primary and secondary sides of the transformer would
then be destroyed. It is thus conventional for the primary-side
controller to receive feedback information about the output voltage
through an isolating communication channel such as an optoisolator.
Although the primary-side controller can then receive feedback
information, the optoisolator causes stability issues and adds
expense to the flyback converter design.
[0005] To avoid such stability and expense, flyback converter
design evolved to use primary-only feedback. In primary-only
feedback, the primary side senses the voltage on an auxiliary
winding (or on the primary winding) at the moment when the
secondary current has ramped down to zero following a cycling of
the power switch. This moment is referred to as the transformer
reset time and represents an ideal time to sample the output
voltage indirectly through the auxiliary winding voltage since
there is a linear relationship between the output voltage and the
auxiliary winding voltage at the transformer reset time. But
following the transformer reset time, the auxiliary winding voltage
will begin resonantly oscillating. It is thus difficult to sample
the auxiliary winding voltage at the precise moment of the
transformer reset time. Moreover, noise and other non-idealities
limit the accuracy of primary-only feedback. For example, the
accuracy of regulating the output voltage through primary-only
feedback is limited by non-perfect coupling of the transformer,
secondary-side rectifier diode forward voltage drop variation, and
synchronous rectification MOSFET Rds variation, component
variation, and the converter load range and operation
conditions.
[0006] Given the limitations for primary-only feedback, it is
inapplicable to applications that demand extreme accuracy such as
voltage regulation with no more than one per cent error. To provide
additional accuracy, various secondary-side regulation schemes have
been implemented. As implied by the name, secondary-side regulation
involves sensing the output voltage and comparing the sensed output
voltage to a reference voltage to develop an error voltage. The
error voltage is filtered to form a control voltage that is further
processed by a power switch controller to control the power switch
cycling. In one form of conventional secondary-side regulation, the
secondary-side controller does the processing of the control
voltage to generate an activity signal that forces the power switch
to cycle on. In such an embodiment, the primary side may include a
rudimentary controller that then switches the power switch off
after a fixed peak current or on time is reached. Alternatively,
the secondary-side controller may also control the off times as
well as the on times for the power switch.
[0007] In lieu of sending an activity signal to stimulate a power
switch cycle, other embodiments for conventional secondary-side
regulation send the control voltage itself to a primary-side
controller. The primary-side controller may then process the
control voltage to control the power switch cycling accordingly.
But regardless of whether an activity signal or the control signal
is transmitted from the secondary side to the primary side, certain
modes of operation are then hampered by the transition from
primary-side feedback to secondary-side regulation. For example,
the charging of a lithium battery must follow a certain transition
between constant-voltage and constant-current modes of operation.
In particular, modern smartphones are typically rather expensive
yet their lithium battery (or batteries) is integrated permanently
or semi-permanently in the smartphone's housing. Should a flyback
converter destroy the battery through an improper charging
sequence, the entire smartphone is then destroyed. It is thus
critical that the proper constant-voltage and constant-current
modes of operation be properly regulated during the battery
charging process. But a secondary-side controller requires the
insertion of a current sense resistor on the secondary side (or
some other means of sensing the output current) to regulate a
constant-current power delivery to the load. The addition of a
current sense resistor into the output current path on the
secondary side of a flyback converter with conventional
secondary-side regulation lowers efficiency and increases
manufacturing complexity and cost.
[0008] Accordingly, there is a need in the art for improved forms
of secondary-side regulation.
SUMMARY
[0009] To avoid the pitfalls of conventional secondary-side
regulation, a flyback converter is provided in which the
primary-side controller retains primary-only feedback capability.
For example, the primary-side controller may include a waveform
analyzer that senses an auxiliary winding voltage through a Vsense
pin or terminal. As known in the primary-only feedback arts, a
waveform analyzer samples the Vsense pin voltage at the transformer
reset time. But unlike conventional primary-only feedback, the
output voltage regulation is not based on the sampled Vsense pin
voltage. Instead, the output voltage regulation is based on
secondary-side regulation (SSR).
[0010] In particular, the primary-side controller may calculate a
desired peak current for the power switch transistor in a current
power switch cycle based upon the output voltage feedback from SSR.
For example, the secondary-side controller may compare the output
voltage to a reference voltage to generate an error voltage that is
then filtered in a loop filter to produce a control voltage. The
secondary-side controller then transmits the control voltage to the
primary-side controller. This control voltage is for implementing a
constant-voltage mode of operation. For example, the primary-side
controller may translate the control voltage into a switching
frequency for pulse frequency modulation that would produce the
desired constant output voltage. Alternatively, the primary-side
controller may translate the control voltage into a peak current
for the current power switch cycle that will produce the desired
constant output voltage. But note the intelligent modulation that
is achieved by retaining the ability to determine the transformer
reset time, waveform shape, and timing information such as the
voltage level, ring resonant period, and valley and peak detection
from the sensing of the auxiliary winding (in alternative
embodiments, the primary winding voltage itself may be sensed to
determine these factors). Since the primary-side controller knows
the peak current at which the power switch transistor was cycled
off, it also knows the peak current for the secondary winding
current given the turn ratio of the transformer. The primary-side
controller may thus determine the average output current based upon
peak secondary current and the transformer reset time since the
secondary winding current only flows over the duration of the
transformer reset time. The primary-side controller may then adjust
the peak current for a subsequent power cycle so that a desired
output current is not violated.
[0011] For example, suppose the battery being charged is fairly
depleted such that its voltage is rather low. This voltage may be
communicated by the mobile device to the secondary-side controller
since the charging occurs through a data cable such as a USB cable
or a Lightning cable. Given this battery charge state, there is a
corresponding output current limit (for example, 1 A, or 2 A,
etc.). Should the output current exceed this limit, the battery
could be damaged. The secondary-side controller may communicate
this output current limit to the primary-side controller, which
then monitors the transformer reset time accordingly to control
whether a constant-current mode of operation should be instituted.
The resulting regulation is thus quite advantageous because the
output voltage accuracy of secondary-side regulation is enjoyed
without the power-robbing need for a secondary-side sense resistor
to enforce constant-current modes of operation should the output
current exceed a constant-current limit. In addition, the
intelligent detection and process of the Vsense waveform shape and
timing information (as used herein, "Vsense" refers to the voltage
signal being sensed using primary-only feedback techniques,
regardless of whether such a voltage signal is derived from the
auxiliary winding or from the primary winding) can achieve
additional features, such as enabling smooth power converter
startup, valley mode switching, as well as protections against
various abnormal and fault conditions.
[0012] These advantageous features and additional inventive
features may be better appreciated through a consideration of the
detailed description below.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1 is a circuit diagram of an improved flyback converter
with hybrid secondary-side regulation in accordance with an aspect
of the disclosure.
[0014] FIG. 2 shows the auxiliary winding voltage waveform during
the detection of the transformer reset time.
[0015] Embodiments of the present disclosure and their advantages
are best understood by referring to the detailed description that
follows. It should be appreciated that like reference numerals are
used to identify like elements illustrated in one or more of the
figures.
DETAILED DESCRIPTION
[0016] Turning now to the drawings, an example flyback converter
100 is shown in FIG. 1. A primary-side controller 105 includes a
switch controller 111 for controlling the cycling of an NMOS power
switch transistor M1. In alternative embodiments, other type of
power switch transistors may be used such as GaN power switch
transistor or a bipolar junction power switch transistor. When
power switch transistor M1 is cycled on, a magnetizing current
begins to flow through a primary winding T1 of a transformer 101
depending upon the input voltage Vin on an input voltage rail and
the magnetizing inductance of primary winding T1. As known in the
flyback converter arts, switch controller 111 may cycle power
switch transistor M1 using valley-mode switching during low to
moderate load levels. During high power modes of operation,
however, it is more advantageous to cycle power switch transistor
M1 using zero voltage switching.
[0017] To implement zero voltage switching, the drain of power
switch transistor M1 connects to a source of an NMOS high side (HS)
switch transistor that has a drain connected to the input voltage
rail through a capacitor C. To effect zero voltage switching,
switch controller 111 may cycle on the HS switch transistor after
the power switch transistor M1 has been cycled off. The leakage
inductance energy for winding T1 is then stored on capacitor C.
When the HS switch transistor is cycled off, the drain of power
switch transistor M1 will be pulled to ground. To detect the zero
crossing for this drain voltage, switch controller 111 may include
a zero-crossing detector such as a comparator 155 that compares the
drain voltage to ground. When comparator 155 indicates that the
drain voltage is discharged, switch controller 111 may then cycle
on power switch transistor M1 in a subsequent switching cycle with
the drain-to-source voltage for power switch transistor M1 being
zero as known in the zero voltage switching arts.
[0018] A secondary winding Si for transformer 101 does not conduct
while the power switch transistor M1 is on. For example, a
secondary-side controller 110 may include a synchronous rectifier
(SR) controller 135 that monitors the drain-to-source voltage for
an NMOS SR switch transistor. When the drain-to-source voltage for
the SR switch transistor indicates that power switch M1 is switched
off, SR controller 135 cycles on the SR switch transistor. As will
be explained further herein, the on control of the SR switch
transistor may be further responsive to a communication from
primary-side controller 105 that power switch transistor M1 has
been cycled off In this fashion, the danger of punch through in
which the SR switch transistor is cycled on while power switch
transistor M1 is still conducting is avoided. SR controller 135 may
also monitor the source-to-drain voltage for the SR switch
transistor to determine when to cycle off the SR switch
transistor.
[0019] Advantageously, secondary-side regulation of the output
voltage is only implemented during steady-state operation. As will
be explained further herein, primary-only feedback information is
used by primary-side controller 105 to control a smooth start-up
mode prior to the transition to steady-state operation. To perform
secondary-side regulation of the output voltage during steady-state
operation, secondary-side controller 110 includes an error
amplifier 140 that generates an error voltage Verr responsive to a
difference between the output voltage VBUS for the flyback
converter and a reference voltage such as a bandgap voltage from a
bandgap (BG) source 145. Note that a scaled version of both these
voltages may be applied to error amplifier 140 in alternative
embodiments. A loop filter 145 filters the error voltage to produce
a control voltage Vc. This control voltage may then be communicated
to primary-side controller 105 as discussed further herein.
[0020] The secondary winding current that flows when the SR switch
transistor is on charges an output capacitor Cout with the output
voltage VBUS. This output voltage charges a load (not illustrated)
through a data cable interface such as a USB cable interface 130
that also includes a D+ terminal, a D- terminal, and a ground
terminal as known in the data cable interface arts. A communication
interface 150 monitors the data terminals D+ and D- to detect
whether a mobile device has been connected to the data cable
interface. Should a mobile device be detected, secondary-side
controller 110 may alert primary-side controller 105 through an
isolating communication channel such as a signal transformer 170
having a secondary winding S2 and a primary winding T3. Alternative
isolating communication channels include an optoisolator such as
formed through a photodiode 160 and a receiving bipolar junction
transistor 165. Alternatively, a capacitor (not illustrated) may
also be used to form a suitable isolating communication channel.
Advantageously, signal transformer 170 is bidirectional so that it
supports communication from secondary-side controller 110 to
primary-side controller 105 as well as from primary-side controller
105 to secondary-side controller 110.
[0021] Communication interface 150 transmits the control voltage
using digital or analog signaling through secondary winding S2 to
induce a corresponding digital or analog signal on primary winding
T3 that is received by communication interface 125. In alternative
embodiments, the error voltage may be transmitted such that
primary-side controller 105 would perform the loop filtering.
Communication interface 125 may then recover the control voltage
(or error voltage) as a digital or analog signal so that it may be
processed by switch controller 111. Switch controller 111 may then
process the control voltage into either a pulse switching frequency
as used in pulse frequency modulation or into a peak switch current
for pulse width modulation as known in the flyback arts. Regardless
of whether power switch transistor M1 is cycled according to pulse
frequency or pulse width modulation, switch controller 111 will
cycle power switch transistor M1 on and off accordingly. For
example, in a pulse width modulation mode of operation, switch
controller 111 determines a peak current for a current switching
cycle for power switch transistor M1 responsive to the processing
of the control voltage. This processing may involve the use of
proportional-integral (PI) or a proportional-integral-differential
(PID) control as known in the flyback arts. During the on-time for
power switch transistor M1, switch controller 111 monitors the
drain current ID conducted by power switch transistor M1 through a
sense resistor Rs that couples between the source of power switch
transistor M1 and ground. The resulting current sense (CS) voltage
across the sense resistor represents the drain current. When switch
controller 111 detects that the drain current (as sensed through
the CS voltage) equals the desired peak current, it cycles off
power switch transistor M1.
[0022] The resulting cycling of power switch transistor M1 based
upon the processing of the control voltage results in a
constant-voltage mode of operation for the output voltage VBUS. But
as discussed earlier, there are modes of operation such as the
initial stages of charging a discharged battery in which
constant-voltage operation would result in too-high levels of
output current flowing into the battery. To prevent such
potentially dangerous levels of output current from occurring,
primary-side controller 105 uses primary-only feedback techniques
to detect the transformer reset time. Since the peak for the
primary winding current is known, the peak for the secondary
winding current is also known since it is proportional to the peak
winding current through the turn ratio for transformer 101.
Primary-side controller 105 may thus advantageously use the
transformer reset time to calculate the average output current
based upon the switching period, the peak secondary winding
current, and the transformer reset time. Should this average output
current exceed a current limit, switch controller 111 may then
"ignore" the control voltage in the next switching cycle and
instead control the on-time for power switch transistor M1 to
produce the desired peak current as monitored through the
primary-only feedback technique.
[0023] The resulting hybrid control is quite advantageous because
flyback converter 100 then enjoys accurate constant-voltage
operation as implemented through secondary-side regulation without
the power-robbing need for a sense resistor on the secondary side
of transformer 101. To detect the transformer reset time,
primary-side controller 105 may sense an auxiliary winding voltage
on an auxiliary winding T2 through a voltage divider 120. The
resulting divided auxiliary winding voltage is then processed by a
waveform analyzer to detect the "knee" in the auxiliary winding
voltage. This may be better appreciated with reference to FIG. 2,
which shows the auxiliary winding voltage VAUX responding to the
cycling off of the power switch at a time t0. In response, the
auxiliary winding voltage will jump high. Following some Gibbs
oscillation, the auxiliary winding voltage will then slowly ramp
down as the secondary current (not illustrated) ramps to zero. When
the secondary current is depleted, the auxiliary winding voltage
hits its knee at time t1, whereupon it falls rapidly and begins
resonantly oscillating. The duration between times t0 and t1 is the
transformer reset time (TRST).
[0024] It would be conventional in primary-only feedback to detect
an output voltage Vo through inversion of the equation 1 shown in
FIG. 2. But the secondary-side regulation has provided this output
voltage much more accurately. What is desired by primary-side
controller 105 is thus the transformer reset time itself so that
the output current may be determined. As known in the primary-only
feedback arts, there are a number of ways of detecting the knee
(and hence the transformer reset time) as well as other waveform
shape and timing information such as the knee voltage, the duration
of the waveform, the resonant ringing period, and also valley and
peak detection so that the details of waveform analyzer 115 would
be understood to those of ordinary skill in the art. Regardless of
how the transformer reset time is detected by primary-side
controller, switch controller 111 may then proceed to calculate the
output current accordingly.
[0025] But note that the Vsense waveform itself may be also be used
by primary-side controller 105 for purposes besides just detecting
the transformer reset time. For example, primary-side controller
105 may use the knee voltage as well as the current sense voltage
to ensure a smooth transition of the output voltage during startup.
For example, when flyback converter 100 is starting up from zero or
very low output voltage, the output voltage regulation is far away
from its steady state, so that it is difficult to have a smooth
increase of the output voltage. By intelligently processing and
utilizing the Vsense and current sense information in the primary
side, flyback converter 100 can achieve smooth startup, without
overshoot, undershoot, oscillation or other undesirable behaviors.
Once the startup is finished and voltage is settled to close to the
reference point, the primary-side control may switch to the
secondary-side regulation which will achieve much accurate voltage
regulation at steady state. In addition, waveform analyzer 115 may
be configured for valley detection so that switch controller 111
may switch on power switch transistor M1 according to valley-mode
switching. Note also that the ability to monitor the Vsense
waveform enables primary-side controller 105 to detect abnormal or
fault conditions such as auxiliary winding open circuit, a short
circuit, or a soft short circuit. In particular, the Vsense
waveform will stay at zero volts if the auxiliary winding T2 is
grounded due to, for example, a circuit board fault. Waveform
analyzer 115 may then detect this lack of a Vsense waveform so that
switch controller 111 may stop the cycling of power switch
transistor M1. An open circuit for auxiliary winding T3 will also
cause an abnormal Vsense waveform that may be detected by waveform
analyzer 115 so that switch controller 115 may stop the cycling of
power switch transistor M1. Other fault examples may include a
current sense (CS) resistor short (or partial short), CS resistor
open circuit, and controller pins short or open. By intelligently
processing and utilizing these indications at the primary side, the
primary-side controller 105 can detect the abnormality and fault
and perform a quick proper action such as turning off the power
switch, without waiting for secondary-side controller 110 to do the
detection and send the alert which would be too late.
[0026] Those of ordinary skill in the art will also appreciate that
numerous modifications may be made for flyback converter 100. For
example, primary-side controller 105 may alert secondary-side
controller 110 of the on/off status of the HS and M1 power
switches. In this fashion, the dangers of punch-through and also
erroneous zero-voltage switching may be avoided. In addition, the
detection of the transformer reset time enables switch controller
111 to detect for short or open circuits at auxiliary winding T3 so
that secondary-side controller 110 may be alerted accordingly. In
addition, the detection of the transformer reset time and other
waveform shape and timing information enables switch controller 111
to detect for over-voltage or under-voltage conditions so that
primary-side controller 105 may be alerted accordingly. In summary,
the flyback converter will retain primary-only feedback techniques,
features and capability while exploiting secondary-side regulation
for steady-state voltage regulation, and also it will have the
bi-directional communication between primary and secondary sides.
Those of some skill in this art will thus appreciate that numerous
modifications, substitutions and variations can be made in and to
the materials, apparatus, configurations and methods of use of the
devices of the present disclosure without departing from the scope
thereof. In light of this, the scope of the present disclosure
should not be limited to that of the particular embodiments
illustrated and described herein, as they are merely by way of some
examples thereof, but rather, should be fully commensurate with
that of the claims appended hereafter and their functional
equivalents.
* * * * *