TEA6017AT
Digital configurable LLC and multimode PFC controller
Rev. 1 — 11 March 2022
1
Product data sheet
General description
The TEA6017AT is a digital configurable LLC and PFC combo controller for highefficiency resonant power supplies. It includes the LLC controller and PFC controller
functionality. The PFC can be configured to operate in DCM/QR, CCM fixed frequency,
or multimode which supports all operation modes to optimize the PFC efficiency. The
TEA6017AT enables building a complete resonant power supply which is easy to design
and has a very low component count. The TEA6017AT comes in a low profile and narrow
body-width SO16 package. The TEA6017AT complies with the NXP industrial profile.
The TEA6017AT digital architecture is based on a high-speed configurable hardware
state machine ensuring very reliable real-time performance. During the power supply
development, many operation and protection settings of the LLC and PFC controller
can be adjusted by loading new settings into the device to meet specific application
requirements. The configurations can be fully secured to prevent unauthorized copying of
the proprietary TEA6017AT configuration content.
In contrast to traditional resonant topologies, the TEA6017AT shows a very high
efficiency at low loads due to the LLC low-power mode. This mode operates in the power
region between continuous switching (also called high-power mode) and burst mode.
Because the TEA6017AT regulates the LLC output voltage of the system via the primary
capacitor voltage, it has accurate information about the power delivered to the output.
This measured output power defines the mode of operation (burst mode, low-power
mode, or high-power mode). The transition levels of the operating modes can be easily
programmed into the device.
The TEA6017AT contains all protections like overtemperature protection (OTP),
overcurrent protection (OCP), overvoltage protection (OVP), overpower protection (OPP),
open-loop protection (OLP), and capacitive mode regulation (CMR). Each of these
protections can be configured independently and accurately by programming parameters
inside the device.
The device contains both a low-voltage and high-voltage silicon technology for highvoltage start-up, integrated drivers, level shifter, protections, and circuitry assuring zerovoltage switching.
The TEA6017AT/TEA2095T combination gives an easy to design, highly efficient,
and reliable power supply, providing 90 W to 1000 W, with a minimum of external
components. The system provides a very low no-load input power (< 75 mW; total
system including the TEA6017AT/TEA2095T combination) and high efficiency from
minimum to maximum load. This power supply meets the efficiency regulations of Energy
Star, the Department of Energy, the Eco-design directive of the European Union, the
European Code of Conduct, and other guidelines. So, any auxiliary low-power supply can
be omitted.
�TEA6017AT
NXP Semiconductors
Digital configurable LLC and multimode PFC controller
To enhance readability, only typical values are given in this document, except in the
parametric tables (Section 9, Section 10, and Section 11). If values in the text differ from
the values for the same parameter in the parametric tables, the values in these tables are
leading.
2
Features and benefits
2.1 Distinctive features
• Complete functionality of a PFC and LLC controller in a single small-size SO16
package
• Compliant with NXP industrial profile
• Integrated high-voltage start-up
• Integrated drivers and high-voltage level shifter (LS)
• High-side driver directly supplied from the low-side driver output
• Accurate boost voltage regulation
• PFC can be configured to operate in:
– DCM/QR
– DCM/QR/CCM (also called multimode operation)
– CCM fixed frequency
• Integrated X-capacitor discharge without additional external components
• Power good function
• PFC jitter for optimized EMI performance
• Excellent power factor (PF) and total harmonic distortion (THD), as the PFC current
compensates for the input filter current
• Several parameters can easily be configured during evaluation with use of the
graphical user interface (GUI), like:
– Operating frequencies to be outside the audible area at all operating modes
– Soft start and soft stop in burst mode, reducing the audible noise
– Accurate transition levels between operation modes (high-power mode/low-power
mode/burst mode)
– Enabling/disabling the lower power mode
2.2 Green features
•
•
•
•
TEA6017AT
Product data sheet
Valley/zero voltage switching for minimum switching losses
Extremely high efficiency from low load to high load
Compliant with latest energy-saving standards and directives (Energy Star, EuP)
Excellent no-load input power (< 75 mW for TEA6017AT/TEA2095T combination)
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Digital configurable LLC and multimode PFC controller
2.3 Protection features
• Independently configurable levels and timers
• Many protections can independently be set to latched, safe restart, or latched after
several attempts to restart
• Supply undervoltage protection (UVP)
• Overpower protection (OPP)
• Internal and external overtemperature protection (OTP)
• Capacitive mode regulation (CMR)
• Accurate overvoltage protection (OVP)
• Overcurrent protection (OCP)
• Inrush current protection (ICP)
• Brownin/brownout protection
• Disable input
3
Applications
•
•
•
•
•
•
•
•
•
4
Desktop and all-in-one PCs
Gaming power supplies
LCD television
Notebook adapters and general-purpose adapters
Printers
Server
5G supplies
UHD LED television
Industrial applications
Ordering information
Table 1. Ordering information
Type number
TEA6017AT/1
5
Package
Name
Description
Version
SO16
plastic small outline package; 16 leads; body width 3.9 mm
SOT109-1
Marking
Table 2. Marking codes
TEA6017AT
Product data sheet
Type number
Marking code
TEA6017AT/1
TEA6017AT
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Digital configurable LLC and multimode PFC controller
6
Block diagram
DRAINPFC
DIGITAL CORE AND CONTROL
PFCOVP
2.63 V
SNSBOOST
A/D
Valleydet
Vprot(ovp)PFC
V SNSBOOST
475 V
I
start-up
disable
0.39 V
VALLEYDET
SUPIC
Xcap
discharge
GATEPFC
GATEPFC
I o(min)SNSCURPFC
Vdet(SNSCURPFC)
SNSCURPFC
open pin
LLC DRIVERS
GATEHS
IPFC
A/D
SUPHS
LS
GATEHS
GATELS
GATELS
demag
-10 mV
SWITCHING CONTROL
OCP
-0.3 V
Vhs(SNSCAP)
D/A
caph
INTC
capl
OTP
3V
5V
Vls(SNSCAP)
Vmains
12 kΩ
low-power mode
burston
IBI/BO
brownin/brownout
6 kΩ
HB peak/valley
CMR
12 kΩ
FEEDBACK CONTROL
1
:
SNSCAP
D/A
VALLEY /
PEAK
DETECT
A/D
P
HB
LLC CURRENT SENSE
+/-
1
VPOWERGOOD
12 kΩ
OPERATION MODE
LLCOCP
SNSMAINS
+/Plowpwr
= 1.5 V
= 0.1 V
SNSCURLLC
0.96 V
1.2 V
2.4 V
s q
r
# BURST
CYCLES
SNSFB
GND
aaa-034244
Figure 1. Block diagram
TEA6017AT
Product data sheet
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Digital configurable LLC and multimode PFC controller
7
Pinning information
7.1 Pinning
SNSMAINS
1
16 SNSFB
SNSBOOST
2
15 SNSCURLLC (SCL)
SNSCURPFC
3
14 SNSCAP (SDA)
GND
4
GATEPFC
5
GATELS
6
11 HB
HVS
7
10 SUPHS
DRAINPFC
8
IC
13 SUPIC
12 HVS
9 GATEHS
aaa-039315
Figure 2. TEA6017AT pin configuration (SOT109-1)
7.2 Pin description
Table 3. Pin description
TEA6017AT
Product data sheet
Symbol
Pin Description
SNSMAINS
1
sense input for mains voltage and external temperature
SNSBOOST
2
sense input for boost voltage; externally connected to resistive-divided
boost voltage
SNSCURPFC
3
PFC current sense input
GND
4
ground
GATEPFC
5
PFC MOSFET gate driver output
GATELS
6
LLC low-side MOSFET gate driver output and supply for bootstrap
capacitor
HVS
7
high-voltage spacer. Not to be connected.
DRAINPFC
8
internal HV start-up source also used for X- capacitor discharge, valley
detection, and PFC OVP detection; connected to (PFC) drain voltage
GATEHS
9
LLC high-side MOSFET gate driver output
SUPHS
10
high-side driver supply input; externally connected to bootstrap capacitor
(CSUPHS)
HB
11
low-level reference for high-side driver and input for half-bridge slope
detection; externally connected to half-bridge node HB between the LLC
MOSFETs
HVS
12
high-voltage spacer. Not to be connected.
SUPIC
13
input supply voltage and output of internal HV start-up source; externally
connected to an auxiliary winding of the LLC via a diode or to an external
DC supply
SNSCAP
14
LLC capacitor voltage sense input; externally connected to divider across
LLC capacitor
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Digital configurable LLC and multimode PFC controller
Table 3. Pin description...continued
TEA6017AT
Product data sheet
Symbol
Pin Description
SNSCURLLC
15
LLC current sense input; externally connected to the resonant current
sense resistor
SNSFB
16
output voltage regulation feedback sense input; externally connected to
an optocoupler. Output for power good function.
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Digital configurable LLC and multimode PFC controller
8
Functional description
8.1 Supply voltages
The TEA6017AT includes:
• A high-voltage supply pin for start-up (DRAINPFC)
• A general supply to be connected to an external auxiliary winding (SUPIC pin)
• A floating supply for the high-side driver (SUPHS pin)
8.1.1 Start-up and supply voltage
Initially, the capacitor on the SUPIC pin is charged via the DRAINPFC pin. The
DRAINPFC pin is connected to the drain voltage of the PFC MOSFET. Internally, a
high-voltage current source is located between the DRAINPFC pin and the SUPIC pin
(see Figure 3).
PFC
DRAINPFC
Vprot(ovp)PFC
OVP_PROT
VALLEYDET
I = lch(SUPIC) = f(temp)
Vstart(SUPIC)
SUPIC
xcap discharge
aaa-038658
Figure 3. HV start-up
The maximum current of the internal current source is limited to Ich(SUPIC). To limit the IC
dissipation, the charge current is reduced when the current source exceeds its maximum
temperature.
At start-up, when the SUPIC reaches the Vstart(SUPIC) level, it is continuously regulated to
this start level with a hysteresis (Vstart(hys)SUPIC).
When the start level is reached, it reads the internal MTP (multi-time programmable
memory) and defines the settings.
When the settings have been defined, the PFC starts up. When the SNSBOOST reaches
the minimum level Vstart(SNSBOOST), the LLC also starts switching (see Figure 4 and
Figure 5).
When start-up is complete and the LLC controller is operating, the LLC transformer
auxiliary winding supplies the SUPIC pin. In this operational state, the HV start-up source
is disabled.
TEA6017AT
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Digital configurable LLC and multimode PFC controller
When the system enters the protection mode, it cannot be supplied via the auxiliary
winding. So, the SUPIC pin is regulated to Vstart(SUPIC) via the DRAINPFC pin.
During the non-switching period of the burst mode, the SUPIC is regulated to the
Vlow(SUPIC) when SUPIC drops to below this level. It regulates the voltage with a
hysteresis of Vlow(hys)SUPIC. In this way, the system avoids that the SUPIC undervoltage
protection (Vuvp(SUPIC)) is triggered because of a long non-switching period in burst mode.
However, the system must be designed such that the internal current source at the
DRAINPFC pin is only active at start-up and extreme output voltage overshoots, followed
by a long time of non-switching. Continuous use of this current source increases the input
power and affects the lifetime of the product. The DRAINPFC pin is also used for valley
detection, for X-capacitor discharge, and for providing a second PFC OVP protection.
ISNSMAINS
Ibi(SNSMAINS)
on
supic_charge
ISUPIC
VSUPIC
off
Ich(SUPIC)
Vstart(SUPIC)
Vstart(hys)(SUPIC)
Vstart(SNSBOOST)
SNSBOOST
Vout
ISNSFB > Ireg(SNSFB)
mode of operation
No Supply
Measure lmains
PFC startup
Readout settings
LLC startup
Operating
aaa-040659
Figure 4. Start-up sequence and normal operation
TEA6017AT
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Digital configurable LLC and multimode PFC controller
VSUPIC < Vrst(SUPIC)
No supply
VSUPIC > Vstart(SUPIC)
PFC disabled
Readout settings
all settings defined
LLC disabled
Measure
lmains
SUPIC regulated
via DRAINPFC
VSNSBOOST > Vscp(start) and ISNSMAINS > Ibi
PFC start-up
VSNSBOOST > Vstart(SNSBOOST)
LLC start-up
ISNSFB > Ireg(SNSFB)
Operating
aaa-039098
Figure 5. LLC controller flow diagram
When the SUPIC voltage drops to below Vrst(SUPIC), the TEA6017AT restarts.
8.1.2 High-side driver floating supply (SUPHS pin)
As the voltage range on the SUPIC pin exceeds that of the maximum external MOSFETs
gate-source voltage, the external bootstrap capacitor CSUPHS cannot directly be supplied
from the SUPIC.
To provide an external supply for the high-side driver without the need of additional
external components, the GateLS output is designed such that it can drive the lowside MOSFET and supply the high-side MOSFET (patent number US20180234015;
see Figure 6).
TEA6017AT
Product data sheet
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Digital configurable LLC and multimode PFC controller
DSUPHS
GATELS
ID(SUPHS)
SUPHS
CSUPHS
GATEHS
S2
LS
HB
VHB
IC
LM
GATELS
S1
CR
VGateHS - VHB
SUPIC
CSUPIC
VGateLS
aaa-027835
aaa-026790
a. Curves
b. Circuit
Figure 6. High-side driver supply
The external bootstrap buffer capacitor CSUPHS supplies the high-side driver. The
bootstrap capacitor is connected to the low-side driver supply, the GATELS pin, and the
half-bridge node (HB) via an external diode (DSUPHS). When GATELS is active high and
the HB node is pulled low, CSUPHS is charged.
Careful selection of the appropriate diode minimizes the voltage drop between the
GATELS and SUPHS pins, especially when large MOSFETs and high switching
frequencies are used. A great voltage drop across the diode reduces the gate drive of the
high-side MOSFET.
8.2 LLC system regulation
The TEA6017AT regulates the output power by adjusting the voltage across the primary
capacitor. Compared to a standard frequency control loop, it has the advantage that the
control loop has a constant gain and the IC has information about the output power. So,
the operation mode transition levels are derived from the output power.
Although the TEA6017AT uses the primary capacitor voltage as a regulation parameter,
all application values, like the resonant inductances, resonant capacitor, and primary
MOSFETs remain unchanged compared to a frequency-controlled LLC converter. A
secondary TL431 circuitry with an optocoupler connected to the primary SNSFB pin
continuously regulates the output voltage.
TEA6017AT
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NXP Semiconductors
Digital configurable LLC and multimode PFC controller
8.2.1 Output power regulation loop
Figure 7 shows the output power regulation loop of Vcap control as used by the
TEA6017AT. Figure 8 shows a corresponding timing diagram.
Vboost
IC
GATEHS
LS
trafo model
D2
Vout
Ls
Lm
Vcap CONTROL
VSNSCAP
burst
GATELS
D1
Vhs(SNSCAP)
Vls(SNSCAP)
Iburst
q
s
qn r
ISNSFB
Vhs(SNSCAP)
SNSCAP
Vls(SNSCAP)
ISNSFB
Cr
SNSFB
2.5 V
aaa-034989
Figure 7. Regulation loop Vcap control
Iload
Ireg(SNSFB) (80 µA)
ISNSFB
Vhs(SNSCAP)
VSNSCAP
Vls(SNSCAP)
t
GATEHS
GATELS
t1
t2
aaa-031214
Figure 8. Timing diagram of the regulation loop
When the divided resonant capacitor voltage (VSNSCAP) exceeds the capacitor voltage
high level (Vhs(SNSCAP)), the high-side MOSFET is switched off (see Figure 8 (t1)). After a
short delay, the low-side MOSFET is switched on. Because of the resonant current, the
resonant capacitor voltage initially increases further but eventually drops.
TEA6017AT
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Digital configurable LLC and multimode PFC controller
When the divided capacitor voltage (VSNSCAP) drops to below the capacitor voltage
low level (Vls(SNSCAP)), the low-side MOSFET is switched off (see Figure 8 (t2)). After a
short delay, the high-side MOSFET is switched on. Figure 8 shows that the switching
frequency is a result of this switching behavior. In a frequency-controlled system, the
frequency is a control parameter and the output power is a result. The TEA6017AT
regulates the power and the frequency is a result.
The difference between the high and low capacitor voltage level is a measure of the
delivered output power. The value of the primary optocurrent, defined by the secondary
TL431 circuitry, determines the difference between the high and low capacitor voltages.
Figure 8 also shows the behavior at a transient. If the output load increases, the current
pulled out of the SNSFB pin decreases. The result is that the TEA6017AT increases the
high-level capacitor voltage and lowers the low-level capacitor voltage. The output power
increases and eventually the output voltage increases to its regulation level.
To minimize no-load input power of the system, the primary current into the optocoupler
is continuously regulated to Ireg(SNSFB) (see Section 8.4).
8.2.2 Output voltage start-up
At start-up, when the system slowly increases the ΔVSNSCAP, it continuously monitors
the primary current via the SNSCURLLC pin. When the voltage at this pin exceeds the
Vlmtr(ocp) level, increasing the ΔVSNSCAP is on hold until the voltage at the SNSCURLLC
pin drops below the Vlmtr(ocp) level again (see Figure 9). The output current is regulated
and its voltage shows a nice ramp during start-up. It also avoids that during startup the
OCP (overcurrent protection) is triggered. In this way, the LLC converter behaves like a
limited current source during start-up.
VSNSCAP
VSNSCURLLC
Vlmtr(ocp)
VOUT
aaa-026792
Figure 9. LLC start-up behavior
TEA6017AT
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Digital configurable LLC and multimode PFC controller
8.3 Modes of operation
Figure 10 shows the control curve between the output power and the voltage difference
between the high and low capacitor voltage levels.
VSNSCAP
VSNSCAP control
Vhs(SNSCAP)
VSNSCAP
Vls(SNSCAP)
burst mode
low-power mode
high-power mode
Pt(lp)
Pout(max)
aaa-026793
Figure 10. TEA6017AT control curve
When the output power (Pout) is at its maximum, the low capacitor voltage level
(Vls(SNSCAP)) is at its minimum and the high capacitor voltage (Vhs(SNSCAP)) is at its
maximum level. The maximum ΔVSNSCAP (Vhs(SNSCAP) − Vls(SNSCAP)), which is the divided
ΔVCr voltage, corresponds to the maximum output power.
When the output load decreases, the ΔVSNSCAP voltage decreases. As a result, the
output power decreases and the output voltage is regulated. This mode is called highpower mode. Figure 8 shows a timing diagram of the system operating in high-power
mode.
When the output power drops to below the transition level (Pt(lp)), the system enters the
low-power mode. The Pt(lp) level can be initialized via the MTP.
To compensate for the non-switching period in low-power mode, also called hold period,
ΔVSNSCAP is initially increased at entering the low-power mode (see Section 8.3.2). In
low-power mode, the output power is regulated by adapting ΔVSNSCAP, until it reaches a
minimum. The system then enters the burst mode (see Section 8.3.3).
TEA6017AT
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Digital configurable LLC and multimode PFC controller
8.3.1 High-power mode
In high-power mode, the system operates as described in Section 8.2.1. Figure 11 shows
a flow diagram of the high-power mode.
System off
GATELS = on/GATEHS = off
t > ton(min)
VSNSCAP < Vls(SNSCAP)
lprim < -locp
lprim > -lreg(capm)
t > ton(max)
GATELS = off/GATEHS = off
t > tno(min)
lprim ≤ 0
End of HB slope
t > tno(max)
GATELS = off/GATEHS = on
t > ton(min)
VSNSCAP > Vhs(SNSCAP)
lprim > locp
lprim < lreg(capm)
t > ton(max)
GATELS = off/GATEHS = off
t > tno(min)
lprim ≥ 0
End of HB slope
t > tno(max)
explanation flow diagram
settings
exit condition 1
exit condition 2a
exit condition 2b
exit condition 2c
exit condition 2d
settings: actions taken when the system is in this state
exit condition: exit condition 1 has to be fulfilled and one of
the exit conditions 2x
aaa-017758
Figure 11. High-power mode flow diagram
TEA6017AT
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Digital configurable LLC and multimode PFC controller
Initially, GATELS is on and GATEHS is off. The external bootstrap buffer capacitor
(CSUPHS) is charged via the GATELS pin and an external diode. The system remains in
this state for at least the minimum on-time (ton(min)) of GATELS. Before entering the next
state, one of the following conditions must be fulfilled:
•
•
•
•
The VSNSCAP voltage drops to below the minimum VSNSCAP voltage (Vls(SNSCAP))
The measured current exceeds the OCP level (see Section 8.6.15)
The system is close to capacitive mode (see Section 8.6.14)
The maximum on-time (ton(max)), a protection that maximizes the time the high-side or
low-side MOSFET is kept on, is exceeded.
To avoid false detection of the HB peak voltage, the system remains in this state until
the minimum non-overlap time (tno(min)) is exceeded. When this time is exceeded and
it detects the peak of the HB node and the measured resonant current is negative (or
zero), it enters the next state.
If the system does not detect a peak at the HB node, it also enters the next state when
the maximum non-overlap time (tno(max)) is exceeded under the condition of a negative
(or zero) resonant current.
Finally, the third and fourth states (see Figure 11) describe the GATEHS and GATEHS to
GATELS transition criteria which are the inverse of the first two states.
8.3.2 Low-power mode
At low loads, the efficiency of a resonant converter drops as the magnetization and the
switching losses become dominant. A low-power mode ensures high efficiency at lower
loads because it reduces the magnetization and switching losses.
When the output power drops to below the Pt(lp) level, the system enters the low-power
mode (see Figure 10 and Figure 12). It continues switching for 3 half-cycles (low-side,
high-side, low-side) with an MTP selectable duty cycle. To ensure a constant output
power level, it increases the energy per cycle (Vhs(SNSCAP) − Vls(SNSCAP)) at the same
time.
TEA6017AT
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Digital configurable LLC and multimode PFC controller
Iload
high-power mode
low-power mode
Vhs(SNSCAP)
VSNSCAP
VSNSCAP
Vls(SNSCAP)
3 half-cycles
hold
period
tlp
ID1
ID2
aaa-038659
Figure 12. Timing diagram transition high-power mode to low-power mode
As the system continuously tracks the primary capacitor voltage, it knows exactly when
to enter the "hold" period. It can also continue again at exactly the correct voltage and
current levels of the resonant converter. In this way, a "hold" period can be introduced
which reduces the magnetization and switching losses without any additional losses. The
currents ID1 and ID2 (see Figure 12) are the secondary currents through diodes D1 and
D2 (see Figure 7).
When in low-power mode the output power is further reduced, the amount of energy per
cycle (= ΔVSNSCAP) is reduced and the duty cycle remains the same (see Figure 13).
When in low-power mode the system reaches the programmable minimum energy per
cycle (= ΔVSNSCAP), it enters burst mode.
TEA6017AT
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Digital configurable LLC and multimode PFC controller
Iload
Vhs(SNSCAP)
VSNSCAP
Vls(SNSCAP)
ID1
ID2
aaa-017766
Figure 13. Low-power mode: Lowering the energy-per-cycle (ΔVSNCAP)
8.3.3 Burst mode
In burst mode, the system alternates between operating in low-power mode and an
extended hold state (see Figure 14). Because of this additional extended hold period, the
magnetization and switching losses are further reduced. So, the efficiency of the system
is increased.
Figure 14 shows that all operating frequencies are outside the audible area. The
minimum low-power frequency can be set with a parameter. Within a low-power period,
the system is switching at the resonant frequency of the converter, which is typically
between 50 kHz and 200 kHz. The burst frequency (1/Tburst) can be programmed out
side the audible noise area.
low-power
hold
hold
low-power
hold
ISNSFB
100 µA
burst-on
Isec
t lp
Tburst
aaa-043348
Figure 14. Burst mode
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Digital configurable LLC and multimode PFC controller
8.3.3.1 Frequency regulation
When the primary optocurrent (ISNSFB) drops to below Istart(burst) (100 μA typical), a new
burst-on period is started. The end of the burst-on period depends on the calculated
number of low-power cycles. The number of low-power cycles within a burst-on period is
continuously adjusted so that the total burst period (Tburst) is at least the period defined
by the setting (see Figure 15).
I load
ISNSFB
100 µA
burst-on
Isec
Tburst
Vscp(start)
off
off
Y
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Digital configurable LLC and multimode PFC controller
Table 4. Protections overview...continued
Protection
Description
Action
PFC LLC Protection
register
undervoltage
protection mains
restart when the mains
voltage exceeds the brownin
level
off
on/ [1]
off
OVP SNSBOOST overvoltage
protection boost
voltage
restart when
VSNSBOOST < Vreg(SNSBOOST)
off
on/ Y
[1]
off
OVP DRAINPFC
LLC and PFC are either
latched or safe restart
[1]
protections
off
off
Y
Maximum on-time maximum ontime of the PFC
MOSFET
PFC MOSFET switched off;
continue operation
-
-
N
OCP
overcurrent
protection
PFC MOSFET switched off;
continue operation
-
-
N
PFCcoil short
-
LLC and PFC are off,
followed by a safe restart
off
off
Y
Iinrush
inrush current
protection
PFC MOSFET switched off;
PFC switching postponed
off
-
-
-
off
-
-
off
-
off
off
Y
PFC protections
brownout-mains
overvoltage
protection
DRAINPFC
voltage
LLC protections
UVP SUPHS
undervoltage
GATEHS = off
protection SUPHS
pin
UVP SNSBOOST undervoltage
protection boost
OVP SUPIC
restart when
VSNSBOOST > Vstart(SNSBOOST)
output overvoltage LLC and PFC are either
[1]
protection;
latched or safe restart
measured via the
SUPIC pin
Maximum on-time maximum ontime of the LLC
MOSFET
LLC MOSFET switched off;
continue operation
-
-
Y
CMR
capacitive mode
regulation
system ensures that mode of
operation is inductive
-
-
Y
OCP
overcurrent
protection
switch off cycle-by-cycle;
After several consecutive
cycles, LLC and PFC are
either latched or safe restart
off
off
Y
[1]
STARTUP MAX
maximum start-up LLC and PFC are either
[1]
time
latched or safe restart
off
off
Y
OPP
overpower
protection
off
off
Y
[1]
TEA6017AT
Product data sheet
LLC and PFC are either
[1]
latched or safe restart
Selectable via a parameter at the MTP.
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Digital configurable LLC and multimode PFC controller
When the system is in a latched or safe restart protection, the SUPIC voltage is regulated
to its start level via the DRAINPFC pin.
8.6.1 Undervoltage protection SUPIC
When the voltage on the SUPIC pin is below its undervoltage level Vuvp(SUPIC), both the
PFC and LLC converter stop switching. The capacitors at the SUPIC pin are recharged
via the DRAINPFC pin.
When the SUPIC supply voltage exceeds its start level, the system restarts.
8.6.2 MTP fail
At start-up, when the SUPIC reaches 12 V, the system reads the parameters from
the internal MTP. If reading the MTP failed, a protection is triggered. A mains reset is
required before the system starts. During this time, the PFC and LLC remain off.
8.6.3 Internal overtemperature protection (OTP)
An accurate internal temperature protection is provided in the circuit. When the junction
temperature exceeds the thermal shutdown temperature, the PFC and the LLC stop
switching.
The response of the internal OTP follows the setting of the external OTP. It can be either
latched or safe restart.
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Digital configurable LLC and multimode PFC controller
8.6.4 Brownin/brownout and external overtemperature protection
On the TEA6017AT, the mains measurement and external temperature are combined at
the SNSMAINS pin (see Figure 25).
mains-L
mains-N
10/20 MΩ
Rsense
10/20 MΩ
I o(SNSMAINS)
ntc measurement
SNSMAINS
A/D
5V
RNTC
10 nF
6 kΩ
DIGITAL
CONTROL
mains resistor value
Vdet(SNSMAINS)
12 kΩ
aaa-038666
a. Circuit
mains - N
mains - L
VSNSMAINS
ISNSMAINS 0
t1
t2
aaa-030888
b. Timing diagram
Figure 25. Mains and external OTP management
The TEA6017AT continuously measures the SNSMAINS voltage via an A/D converter
and waits until it detects a peak (t1). This peak value is internally stored and used for
the mains compensation. The output of the A/D converter is used for brownout/brownin
detection.
During an NTC measurement, which is enabled during the peak of the mains, an
internal current source of Io(SNSMAINS) is switched on. With the external NTC and diode,
the internal current source generates a voltage at the SNSMAINS pin. If this voltage
remains below the Vdet(SNSMAINS) level, the external OTP protection is triggered after
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Digital configurable LLC and multimode PFC controller
td(otp). The internal current source is turned on until the SNSMAINS voltage exceeds the
Vdet(SNSMAINS) level level or a maximum time of tdet(max)NTC.
The external resistor, which is connected between mains_L/mains_N and the SNSMAINS
pin, can be either 20 MΩ or 10 MΩ. The amount of mains resistor can either be one (only
connected to the mains-L or mains-N) or two (one connected to the mains-L and the
other to the mains-N). However, the selected parameter of the resistor value and number
of resistors must correspond to the application.
8.6.5 Short-circuit protection/fast disable
The PFC and LLC do not start switching until the voltage on the SNSBOOST pin exceeds
Vscp(start). This function acts as short circuit protection for the boost voltage.
When the SNSBOOST pin is shorted to ground or the SNSBOOST pull-up resistor is
disconnected, this protection inhibits switching.
This function can also be used as a fast disable. If this pin is shorted to ground via
an external MOSFET, the system either stops switching or enters the protection
mode followed by safe restart or latched protection. In this way, an additional external
protection can be added.
8.6.6 Brownout mains
To prevent the PFC from operating at very low mains input voltages, the PFC stops
switching with a soft stop when the measured mains voltage drops to below the brownout
level. When the mains voltage exceeds the brownin level, the PFC restarts with a soft
start. To avoid that the system is interrupted during a short mains interruption, a delay
can be set before the brownout function is active.
Typically, only the PFC stops switching and the LLC continues at a brownout. Due to
the large PFC bulk capacitor, the LLC can continue for a long period while the mains is
already disconnected. So, the option to stop the LLC at a brownout after a given delay
can be selected with a parameter.
8.6.7 Overvoltage protection (SNSBOOST pin)
To prevent output overvoltage during load steps and mains transients, a PFC output
overvoltage protection circuit is built in. When the voltage on the SNSBOOST pin
exceeds the Vstop(ovp)PFC level, switching of the power factor correction circuit is inhibited.
When the SNSBOOST pin voltage drops to below the regulation level (Vreg(SNSBOOST))
again, the switching of the PFC recommences.
When an OVP at the SNSBOOST is detected for a minimum period (can be set using a
parameter), the LLC can also be disabled.
8.6.8 Overvoltage protection (DRAINPFC pin)
To prevent output overvoltage of the PFC due to a disturbed SNSBOOST pin, an
additional PFC output overvoltage protection is available. This overvoltage protection is
measured via the DRAINPFC pin.
To avoid false triggering, measuring the DRAINPFC is blanked for tleb(OVP)PFC after the
PFC MOSFET is switched off.
The DRAINPFC overvoltage protection level and the delay before it enters the protection
state can be set with parameters.
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Digital configurable LLC and multimode PFC controller
The DRAINPFC overvoltage protection can be a latched, a safe restart, or a latched after
safe restart protection.
8.6.9 Overcurrent protection, inrush protection (SNSCURPFC pin)
The PFC current is measured via an external sense resistor (RSENSE) connected to
the SNSCURPFC pin (see Figure 29). If the voltage drops to below Vocp(PFC), the PFC
MOSFET is turned off. It resumes switching at the next cycle, under the condition that the
voltage at the SNSCURPFC is above the Vocp(PFC) level. Otherwise, it remains off until
this requirement is fulfilled. It avoids that the PFC MOSFET is turned on during an inrush.
To ensure that the OCP level is not exceeded due to disturbance caused by a turn-on of
the PFC MOSFET, the OCP level is filtered via an internal 1 MHz filter.
8.6.10 PFC coil short protection (SNSCURPFC pin)
If the PFC coil is shorted, the overcurrent protection is triggered continuously. To avoid
overheating, the system enters the protection state when the OCP is continuously
triggered for a selectable number of switching cycles. The PFC and LLC converters stop
switching and a restart follows.
8.6.11 Undervoltage protection SUPHS
To ensure a minimum drive voltage at the high-side driver output (GATEHS), this driver is
turned off when its voltage is below the minimum level (VSUPHS < Vrst(SUPHS)).
8.6.12 Undervoltage protection boost
The PFC output voltage is measured via a resistive divider connected to the
SNSBOOST pin. The voltage at the SNSBOOST pin must exceed the start level
(VSNSBOOST > Vstart(SNSBOOST)) before the LLC converter is allowed to start switching.
When the system is operating and the voltage at the SNSBOOST pin drops to below the
minimum level (VSNSBOOST < Vuvp(SNSBOOST)), the LLC converter stops switching. When it
exceeds the start level, it restarts.
8.6.13 Overvoltage protection
When the voltage at the SUPIC pin exceeds the VO(ovp)SUPIC level for td(ovp)SUPIC, the
OVP protection is triggered. The voltage at the SUPIC pin is continuously monitored via
an internal A/D converter.
The OVP protection level and the OVP delay time can be selected with a parameter.
The OVP function can also be disabled.
8.6.14 Capacitive mode regulation (CMR)
The TEA6017AT has a capacitive mode regulation (CMR) which ensures that the system
is always operating in inductive mode and avoids operation in capacitive mode.
At lower input voltage or higher output power and depending on the resonant design, the
resonant current can already approach zero before the capacitor voltage reaches the
regulation level.
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Digital configurable LLC and multimode PFC controller
When the resonant current has changed polarity before the switches are turned off and
the other switch is turned on, hard switching occurs. This event is called capacitive mode.
To avoid that the LLC operates in capacitive mode, the system also switches off the highside/low-side switch when the resonant current approaches zero.
Figure 26 shows the signals that occur when a resonant converter is switching in
CMR mode. At t1 (and also at t3), the low-side switch is on while the resonant current
approaches zero before VSNSCAP reaches Vls(SNSCAP). At t2, the resonant current is
also close to changing polarity while the divided capacitor voltage (VSNSCAP) has not
reached the Vhs(SNSCAP) level yet. To avoid a turn-off of the high-side switch at a negative
current or the low side at a positive current, the system also turns off the high-side/lowside switch when the primary current approaches zero. So at t2, the high-side switch
is turned off because the primary current is close to zero. At t3 (and also at t1), the lowside switch is turned off, although VSNSCAP did not reach the regulation level (Vls(SNSCAP))
yet. The primary current is measured via an external sense resistor connected to the
SNSCURLLC pin. The capacitive mode protection levels are Vreg(capm) (−100 mV typical
and +100 mV typical). These levels can be adjusted with a parameter.
In this mode, the amount of output power is reduced and the output voltage decreases.
The TEA6017AT does not enter a so-called "capacitive mode protection", but avoids this
mode of operation.
GATEHS
GATELS
HB
Vhs(SNSCAP)
VSNSCAP
Vls(SNSCAP)
Iprim
Vreg(capm)
0
Vreg(capm)
t0
t1
t2
t3
aaa-017772
Figure 26. Near capacitive mode switching
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Digital configurable LLC and multimode PFC controller
8.6.15 Overcurrent protection
The system measures the LLC primary current continuously via a sense resistor
connected to the SNSCURLLC pin. If the measured voltage exceeds the fixed
overcurrent level (Vocp(LLC)), the corresponding switch (GATELS/GATEHS) is turned off,
but the system continues to switch. In this way, the primary current is limited to the OCP
level.
The OCP level can be adjusted via the external sense resistor.
If the OCP is continuously triggered for an adjustable time, the system enters the OCP
protection state. The OCP protection state can also be disabled. However, the primary
current is always limited to the OCP level cycle-by-cycle.
8.6.16 Maximum start-up time
At start-up, the PFC starts switching. When the PFC output voltage exceeds a minimum
level, the LLC starts switching as well.
If the output voltage of the LLC is not in regulation within an adjustable time after the PFC
has started switching, the maximum start-up time protection is triggered.
The maximum start-up time (tstartup(max)) can be set with the parameter “Maximum startup time”. If this protection is triggered, the system is latched, safe restart, or latched after
safe restart, which follows the setting of the OPP.
8.6.17 Overpower protection
For the overpower protection, three levels can be set:
• Absolute maximum output power, which is the highest output power level.
When the output power exceeds this maximum level, it is limited cycle-by-cycle. If the
output power exceeds this maximum, the output voltage decreases.
The maximum output power can be set to a percentage of the rated output power.
• A first overpower level, which is below the maximum output power level.
When the output power exceeds this power level, a timer is started. When this timer
exceeds a predefined value, the system enters the protection state. Both PFC and LLC
are switched off.
This power level can be set to a predefined level below the selected maximum output
power. So, if the maximum output power is set to 170 % and this first overpower level is
set to −20 %, the timer is started at 150 % of the rated output power.
The timer of the first overpower level can also be set. The first overpower level can also
be disabled.
• A second overpower level, which is typically below the first overpower level.
When the output power exceeds this power level, a timer is started. When this timer
exceeds a predefined value, the system enters the protection state. PFC and LLC are
switched off.
This power level can be set to a predefined level below the selected maximum output
power. So, if the output power is set to 170 % and this second overpower level is set to
−50 %, the timer is started at 120 % of the rated output power.
The timer of the second overpower level can be set to a predefined level. The second
overpower level can also be disabled.
The overpower function can be either latched, safe restart, or latched after safe restart.
Section 8.6.18 describes this function.
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Digital configurable LLC and multimode PFC controller
8.6.18 Latched, safe restart, or latched after safe restart
When a protection is selected to be latched, the system stops switching when
this protection is triggered. The system only restarts after a fast latch reset
(see Section 8.6.19) or when the SUPIC supply voltage drops below the UVP level.
When a protection is selected to be safe restart, the system continuously restarts after a
predefined safe restart time. This safe restart time is the same for all protection functions.
It can be set with a parameter.
When selecting “latched after safe restart”, a protection is initially a safe restart
protection. If the failure occurs again within a specific time, it latches eventually.
latched after saferestart
OVP
latched
protection
65 sec
restart counter
0
1
2
3
0
1
2
3
4
aaa-038667
Figure 27. Latched after safe restart
Figure 27 shows an example of when the OVP is set to latched after safe restart. Initially
at an OVP, the system restarts after the safe restart time. An internal counter is then set
to ‘1’. If the protection is triggered again, the counter is increased. If the counter reaches
the number as set with a parameter, the system latches. If no protection is triggered
within 65 seconds, the counter is reset.
8.6.19 Fast latch reset
If a protection is triggered, the system enters the protection state. Especially when the
protection is latched, this function is inconvenient during production tests. So, when the
mains voltage is below the brownout level for a specified time, the system also restarts.
This time can be set with a parameter. This function is called fast latch reset.
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Digital configurable LLC and multimode PFC controller
8.7 Power good function
The TEA6017AT provides a power good function via the SNSFB pin.
FEEDBACK CONTROL
1
SUPIC
:
1
power level
V(SNSFB)
12 kΩ
SNSFB
POWERGOOD
aaa-027838
aaa-038668
a. Primary side
b. Secondary side
Figure 28. Power good function
The primary function of the SNSFB pin is to regulate the output voltage via an
optocoupler. So, it measures the current that is drawn from the SNSFB. Via an internal
12 kΩ resistor, it regulates the output power. The output power regulation is independent
of the voltage level of the SNSFB pin. So, the voltage level at the SNSFB pin is used
to indicate if the system is about to stop operating, a so-called power good signal. The
voltage at the SNSFB pin can be used to generate a secondary power good signal using
an external MOSFET and an optocoupler.
At start-up, the SNSFB voltage is at a high level, pulling down the secondary power good
signal. As soon as the system enters the operating state (see Figure 4), the SNSFB goes
low. The external power good signal becomes active high.
The SNSFB voltage becomes active high, lowering the secondary power good signal
when:
•
•
•
•
The voltage on the SNSBOOST pin drops to below Vdet(SNSBOOST)
The OPP counter is close to its end value
The converter is about to stop due to an OTP protection
When the LLC converter is about to stop due to an OVP on the SNSBOOST when this
function is enabled
• When the LLC converter is about to stop due to a mains brownout when this function is
enabled
To avoid any disturbance of the regulation loop, the increase and decrease of the SNSFB
voltage is in alignment with a predefined ramp.
When the system enters protection mode (OVP, OCP, or UVP), it pulls high the SNSFB
pin and stops switching immediately.
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Digital configurable LLC and multimode PFC controller
8.8 Settings
The TEA6017AT has an internal MTP at which different settings can be programmed.
Disclaimer:
The MTP parameter settings can be changed using the “Ringo” GUI software of NXP
Semiconductors. Before the user can change any MTP parameters using the GUI, the
terms and conditions in the start-up pop-up screen must be accepted.
8.8.1 General settings
8.8.1.1 Protection register
When the TEA6017AT triggers a protection, it can be read which protection was
triggered. Even when the root cause of the protection is solved and the converter
continues switching, the information about the protection remains until the software
program (Ringo GUI) clears it.
8.8.1.2 Supply start level
The SUPIC start level can be selected between 12 V and 19 V. Typically, a level of 19 V
is selected. When the TEA6017AT is externally supplied, for instance via a standby
supply, the lower start level of 12 V can be used.
After start-up, when the MTP is read and a 12 V start level is selected, charging via the
PFCDRAIN is disabled, as the system assumes that it is externally supplied.
8.8.1.3 Read lock
Normally, the software tool can read all the programmed settings. This option can be
used to verify the correct settings or for failure analyses.
However, once in production, enabling the "Read lock" bit protects the parameters. Then
it is not possible anymore to read the MTP content. It can however still be reset to the
default values and also clear the read lock parameter.
8.8.1.4 Write lock
To avoid that the MTP content (accidentally) gets overwritten, a write-lock bit can be set.
It can, however, still be reset to the default values and clear the write lock parameter.
8.8.1.5 Reset to the default values
When the MTP is reset, it implies that all parameters are set to a default value. The
default values normally do not correspond to the original MTP values. They are chosen
such that a general application works properly.
When the MTP is reset, the MTP can be read and written again.
8.8.1.6 Customer MTP code
When in production, the content of the MTP can be hidden when the read lock bit is
enabled. To get access to the content of the MTP, a unique customer code can be
programmed. This customer code provides information about the MTP content.
This customer code can always be read, even when the read lock bit is enabled.
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Digital configurable LLC and multimode PFC controller
8.8.2 PFC settings
8.8.2.1 Soft-start time
For the start-up time of the PFC, the following RC time periods can be selected: 12.8 ms,
25.6 ms, 51.2 ms, or 102.4 ms.
8.8.2.2 Active X-capacitor discharge
When the TEA6017AT detects that the mains is disconnected, the X-capacitor discharge
is activated after a delay of td(dch)xcap. The following delays can be selected: 100 ms,
200 ms, and 400 ms. This function can also be disabled.
8.8.2.3 Mains measurement impedance
To realize a low no-load input power level, the external resistor connected to the
SNSMAINS pin for measuring the mains input voltage is typically 20 MΩ.
However, some applications request a maximum resistance of 10 MΩ. With this bit,
10 MΩ or 20 MΩ can be selected for the external resistor without affecting the mains
voltage-related levels like brownin and brownout.
8.8.2.4 Number of mains resistors
To achieve the lowest possible no-load input power, a single mains sense resistor can be
used. If continuously measuring the mains voltage is necessary, two mains resistors can
be used.
For proper functionality, the resistor value and number of resistors in the application are
required to correspond to the IC settings.
8.8.2.5 PFC mode of operation
When all modes are enabled, the PFC can operate in DCM, QR, or CCM mode.
However, the frequency varies between the minimum and maximum frequency.
It is also possible to either disable CCM mode or select the fixed frequency mode. For
evaluation purposes, the option to disable the PFC is available as well.
8.8.2.6 PFC minimum and maximum frequency
The minimum switching frequency of the PFC can be set within a range from 25 kHz
to 80 kHz. When the CCM mode of operation is disabled, the PFC always waits until
the PFC coil is demagnetized before starting the next cycle. As a result, the switching
frequency can drop to below the minimum frequency.
The maximum frequency can be set within a range from 75 kHz to 250 kHz. When the
PFC operating mode is set to fixed frequency, the frequency can be set between 55 kHz
and 200 kHz.
8.8.2.7 Burst mode: Output voltage ripple
When the PFC enters burst mode, it stops switching when the SNSBOOST voltage,
which reflects the PFC output voltage, reaches its regulation level and the LLC stops
switching. When the voltage at the SNSBOOST pin has dropped to a programmed level,
the PFC is enabled again. For the difference between these two levels the following
values can be selected: 70 mV, 105 mV, 140 mV, 175 mV, 210 mV, 245 mV, and 280 mV.
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Digital configurable LLC and multimode PFC controller
These values typically correspond with a ripple on the PFC output voltage of 10 V, 16 V,
22 V, 28 V, 34 V, 40 V, and 46 V.
The PFC burst mode can also be synchronized to the LLC burst mode. It then follows
the on and off periods of the LLC. However, it ensures that the SNSBOOST reaches its
regulation level.
8.8.2.8 Burst mode: Soft-start/soft-stop time
To minimize audible noise of the PFC, a burst mode soft start and soft stop can be
independently selected. The selectable values are: normal, short, and long. The
additional soft-start and soft-stop can also be disabled.
8.8.3 LLC settings
8.8.3.1 LLC disable
Especially for validation purposes, an option is available to disable the LLC. When the
LLC is disabled, a restart is required.
8.8.3.2 Start-up
Maximum (start-up) frequency
The maximum switching frequency of the LLC is limited to a value, which is defined using
a parameter. This value also defines the maximum switching frequency during start-up.
The maximum frequency can be set to different values ranging from 150 kHz to 800 kHz.
LLC soft-start time
The LLC soft-start time defines the rate at which the converter lowers its switching
frequency. This rate can be selected between 2 and 20 which leads to a start-up time
of approximately between 1 ms and 10 ms. However, it depends on the LLC design. A
higher speed lowers the start-up time. However, it can cause a high charge current and
an overshoot at the output voltage.
Maximum primary current during start-up
At start-up, the LLC starts switching at the maximum frequency and ramps down the
frequency until the ΔVSNSCAP reaches the required level. If during this start-up time
the primary current, which reflects the output current, reaches a predefined level, the
frequency is temporarily not further reduced until the primary current drops to below the
level again. This level is measured via the SNSCURLLC pin. The following values can be
selected: 0.5 V, 0.75 V, 1.0 V, or 1.25 V.
8.8.3.3 LLC switching
ΔVSNSCAP dump level
When the system is in low-power mode, a switching period is followed by a waiting
period. The system ensures that it continues at the same stage as where it stopped. To
reach the maximum efficiency, the end of the last switching cycle can be fine-tuned. For
the ΔVSNSCAP dump level, values between 2.525 V and 2.7 V can be selected in steps of
25 mV.
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Digital configurable LLC and multimode PFC controller
Minimum non-overlap time
To ensure that the GATEHS is properly turned off before the GATELS is turned on, and
vice versa, there is a minimum non-overlap time. For the minimum non-overlap time, the
following values can be selected: 100 ns, 230 ns, 350 ns, 500 ns.
Maximum non-overlap time
When the system does not detect a valley at the HB node after turning off GATEHS, the
system turns on the GATELS after the maximum non-overlap time. The same counts
when a peak at the HB node is not detected after turning off the GATELS and turning on
the GATEHS. For the maximum non-overlap time, the following values can be selected:
0.5 μs, 0.7 μs, 0.9 μs, or 1.1 μs.
Maximum on-time
When the on-time of the GATELS or GATEHS exceeds the maximum on-time, the switch
is turned off and the LLC converter starts the next cycle. For the maximum on-time, the
following values can be selected: 10 μs, 20 μs, 30 μs, or 38 μs.
Capacitive mode regulation
When the voltage at the SNSCURLLC pin, which reflects the resonant current, drops to
below a predefined value, the LLC converter starts the next switching cycle. In this way,
the TEA6017AT avoids that the converter operates in capacitive mode. For the capacitive
mode regulation, the following values can be selected: 20 mV to 160 mV in steps of
20 mV.
LLC maximum ringing time
When the LLC operates in LP mode, it counts the amount of ringings. If a ringing is not
detected, it assumes a peak after the timeout. This timeout can be set to 3 μs, 5 μs,
7.5 μs, or 10 μs. The appropriate value depends on the application. It must be chosen
just above the maximum ringing period.
8.8.3.4 Feedback
Optocoupler current
To achieve a low no-load input power, the current through the optocoupler must be set
at a low level. However, depending on the selected optocoupler, a higher optocoupler
current may be requested. So, the optocoupler current can be set to different values
ranging from 80 μA to 1.2 mA.
8.8.3.5 Operation modes
HP-LP transition level
When the output power drops to below a predefined level, the system switches from the
HP to the LP mode. The HP-LP transition level can be set to different values ranging from
10 % to 54 %.
HP-LP transition hysteresis
When the system operates in LP mode, it switches over to HP mode when the output
power exceeds the selected HP-LP transition level plus a hysteresis. For the hysteresis,
the following values can be selected: 10 %, 20 %, 30 %, or 40 % of the selected HP-LP
transition level. So, if the rated output at 100 % is 100 W, the HP-LP transition level is set
at 30 % and the hysteresis is set at 10 %. The eventual hysteresis is 3 W.
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Digital configurable LLC and multimode PFC controller
LP-BM transition level
When the output power drops below the LP-BM transition level, the system enters burst
mode. The LP-BM transition level can be set to different values ranging from 1 % to
25 %.
The actual LP-BM transition level can deviate from the selected value due to delays in
the system. The deviation is most noticeable at low LP-BM transition levels. In this case,
the LP-BM transition level can be fine-tuned in steps of 1 %.
BM-LP transition level
When the system operates in burst mode and output power increases to exceed the LPBM transition level plus a hysteresis level, the system enters low-power mode. For the
hysteresis, levels in the range from 5 % to 50 % can be selected, which are related to
the selected LP-BM transition level. So, if the rated output at 100 % is 100 W, the LPBM transition is set at 10 %, and the hysteresis at 50 %, the system switches from burst
mode to low-power mode at a level of 15 W.
BM-LP transition level filter
When the output power slowly increases, the system ensures a smooth transition when
leaving burst mode and entering low-power mode by setting a burst-mode-to-low-powermode transition filter. When the output power exceeds the BM-LP transition level plus
hysteresis for 2, 4, 8, or 16 burst cycles, it leaves the burst mode and enters the lowpower mode. At a large transient at the output, the system immediately leaves burst
mode.
BM repetition frequency
When the system operates in burst mode, it is regulated to a fixed frequency. This
frequency can be set to different values ranging from 20 Hz to 3.2 kHz.
BM E/C (Energy-per-cycle) increase
As the TEA6017AT regulates the output via the primary capacitor voltage, it offers the
ability to increase the output power per switching cycle when it enters burst mode. For
the increase of output power per switching cycle, also called E/C (Energy-per-cycle),
different values can be set ranging from 1 to 4. When, for instance, the E/C is set to 4,
the system increases the E/C with a factor of 4 when it enters burst mode. The initial
duty cycle is then 25 %. Increasing the E/C in burst mode increases the efficiency of the
system, but at the cost of a higher output voltage ripple.
BM soft start/soft stop
To minimize the audible noise in burst mode, a soft start and a soft stop can be added.
The soft start and soft stop can be independently initialized, whereas the number of softstart/soft-stop cycles can be set between 0 and 4. In this way, the soft-start and soft-stop
cycle can be optimized depending on the selected transformer.
BM minimum cycles
As additional soft-start and soft-stop cycles reduces the audible noise, it increases the
switching losses. To optimize the number of normal switching cycles in relation to the
added soft-start and soft-stop switching cycles, the minimum number of normal switching
cycles that can be selected ranges from 1 to 12.
Burst end SNSFB current
When the system operates in burst mode, it adjusts the number of switching cycles
such that burst frequency corresponds to the selected burst frequency. If during these
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Digital configurable LLC and multimode PFC controller
switching cycles the output load decreases, the output voltage increases as the system
has calculated the number of required switching cycles. If the measured optocoupler
current at the SNSFB pin exceeds a certain level, the system ends the burst switching
cycle. This level can be between a factor of 2.5, 3.75, 5, or 7.5 times the selected
optocoupler current level.
Burst delay
Entering the burst mode can be postponed with a delay from 0.2 s to 4 s. The delay can
also be set to 0, implying that when the output power drops to below the burst mode
entry level, the system immediately enters burst mode. The burst mode delay can also be
set to infinite. The system does not enter burst mode and remains switching.
Burst-mode exit delay
When the LLC is switching for a time that exceeds the burst-mode exit delay time and the
output load exceeds the burst-mode level, the system leaves the burst mode. The burstmode exit delay time (tburst-exit) can be set from 160 μs to 4 ms in 16 steps.
Low-power frequency
The frequency of the low-power mode can be selected by defining the ringing number at
which the next low-power cycle must be started. The selection options are from 1 to 8 in
steps of 1.
SNSBOOST compensation
A ripple at the input voltage of an LLC converter normally results in a ripple in the output
voltage. To minimize the ripple at the output voltage, the TEA6017AT measures the input
voltage of the LLC via the SNSBOOST pin and compensates the SNSCAP voltage via
a feed-forward compensation. As the required compensation depends on the external
components, it can be set at 8 different compensation levels.
8.8.4 Protection settings
8.8.4.1 General protections
Fast latch reset delay time
When the system does not detect a mains voltage for a programmed period, it assumes
that the mains is disconnected and resets all protections. When the mains voltage
exceeds the brownin level again, the system restarts. The delay between detecting
a brownout (including the brownout delay time) and resetting all protections can be
programmed to different values ranging from 0 s to 10 s.
Safe restart time
When the system is in protection mode and the triggered protection is programmed as
safe restart, it restarts after a safe-restart time. This time can be set at different values
ranging from 0.5 s to 10 s.
Fast disable
When the SNSBOOST voltage is pulled below the Vscp(stop) level, the system enters the
protection state. The response can be set to on/off, latched, or safe restart.
External OTP level
The external application temperature is measured via an NTC connected to the
SNSMAINS pin. To be able to set the appropriate NTC value and OTP level, the internal
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Digital configurable LLC and multimode PFC controller
current used to measure the external NTC value can be set between 150 µA and
1050 µA in steps of 150 µA.
To avoid false triggering, an internal delay occurs before the system enters protection.
This delay can be set to different values between 0.5 s and 8 s.
The response of the external OTP can be latched, safe restart, or latched after safe
restart. The external OTP function can also be disabled.
Internal OTP level
The internal OTP is fixed at 135 °C. When the internal OTP is triggered, it follows the
same response as selected for the external OTP, being either latched, safe restart, or
latched after safe restart.
8.8.4.2 PFC general protections
Brownin/brownout level
For the brownin level, several values can be selected ranging from 67 V (AC) to 185 V
(AC). For the hysteresis between the brownin and brownout level several values can be
selected from 2 V (AC) to 17 V (AC). The given values depend on the resistor values in
the application and their tolerances.
When the mains voltage is below the brownout period for a selectable amount of time,
the system enters the brownout state. For this time, several values can be selected
ranging from 25 ms to 1.2 s.
PFC OCP level
The PFC OCP level is fixed to Vocp(PFC). The external sense resistor can select the
corresponding current value.
PFC maximum on-time
The maximum on-time of the PFC equals 1 / minimum frequency. Where the minimum
frequency set by the MTP and the possible additional frequency jitter defines the
minimum frequency.
PFC coil short protection
When the PFC continuously triggers the OCP, the system enters the protection state for
a selectable number of switching cycles. The number of switching cycles can be set to
2500 cycles, 5000 cycles, or 12500 cycles. This function can also be disabled.
PFC output OVP
The PFC output voltage is measured via the SNSBOOST pin and the DRAINPFC pin.
For the OVP at the SNSBOOST pin, the following values can be selected: 2.60 V, 2.63 V,
2.65 V, or 2.70 V.
When an OVP is detected at the SNSBOOST pin, the PFC stops switching and continues
again when its voltage drops below the regulation level.
For the OVP at the DRAINPFC pin, the following values can be selected: 475 V, 500 V,
525 V, or 550 V. To avoid false triggering, a delay can be selected of 100 cycles,
250 cycles, or 1000 switching cycles. During this delay, the output voltage of the PFC is
limited to this maximum value.
The response of an OVP at the DRAINPFC pin can be latched, safe restart, or latched
after safe restart. This function can also be disabled.
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Digital configurable LLC and multimode PFC controller
Valley detection timeout
When the PFC MOSFET is off and the current through the PFC coil becomes zero, the
coil is demagnetized. Normally, shortly after the demagnetization, the drain voltage starts
to ring and a valley is detected. When the system detects demagnetization but does not
detect a valley shortly after, the ringing may be too small to detect a valley. So, when
demagnetization is detected, it assumes a valley within a specified time. For this time, the
following values can be selected: 2 μs, 3 μs, 5 μs, or 7 μs.
PFC minimum off-time
To avoid false triggering of the demagnetization and valley detection, a minimum offtime of the PFC driver output can be selected. The available values are 500 ns, 750 ns,
1000 ns, and 1500 ns.
8.8.4.3 LLC general protections
Maximum start-up time
When the LLC starts switching, it expects that its output voltage reaches the regulation
level within a maximum start-up time. For the maximum start-up time, the following
values can be selected: 25 ms, 50 ms, 100 ms, and 200 ms.
LLC brownout level (SNSBOOST)
When the voltage at the SNSBOOST drops below a predefined level, the LLC converter
enters the protection state. When the SNSBOOST voltage exceeds the brownin level, the
LLC converter starts switching again.
For the LLC brownout level at the SNSBOOST, a level in the range from 1.0 V to 2.05 V
can be selected.
LLC brownin level (SNSBOOST)
The LLC brownin level defines the minimum voltage at the SNSBOOST pin before the
LLC starts switching. For this level, a value ranging from 1.5 V to 2.4 V can be selected.
LLC brownout timer (SNSMAINS)
When the mains is disconnected, the PFC stops switching after its brownout delay.
Normally, the LLC converter continues switching until the input voltage of the LLC drops
to below a minimum (Vuvp(SNSBOOST)) level. Especially at a minimum load at the output,
the LLC dropping to the minimum level can take a long time.
A timer can be initialized that also disables the LLC converter when a brownout is
detected at the mains input. For this time, a value can be selected ranging from 125 ms
to 6 s. The option that the LLC converter remains switching until its input voltage drops to
below a minimum level can also be selected.
LLC maximum input voltage (SNSBOOST)
When an OVP is detected on the SNSBOOST pin, the PFC always stops switching. The
response of the LLC can be set to either continue operation or stop switching until the
voltage the SNSBOOST drops to below the PFC output voltage regulation level. A delay
can be set to either 5 ms, 50 ms, or 1250 ms.
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Digital configurable LLC and multimode PFC controller
Power limit
The maximum output power of the converter is limited by the controller. The limitation
ensures that the applied load is below the maximum rating-selected components. For the
maximum output power, several levels between 100 % and 200 % of the rated power can
be selected.
OPP level 1
When the output power exceeds a first OPP level, a first counter is started. When the
output power continuously exceeds this OPP level for a selected period, the system
enters protection state. For the OPP level, a level between 0 % and −50 % below the
selected power limit can be selected.
For the time, a value between 50 ms to 40 s can be selected. The response of this
protection can be latched, safe restart, or latched after safe restart. This OPP level can
also be disabled.
OPP level 2
When the output power exceeds a second OPP level, a second counter is started. When
the output power continuously exceeds this OPP level for a selected period, the system
enters protection state. For the OPP level, a level in the range from −10 % to −50 %
below the selected power limit can be selected.
For the time, a value ranging from 50 ms to 3 s can be selected. The response of this
protection follows the selected response of the OPP level 1. This OPP level can also be
disabled.
OPP duty cycle
When the output power exceeds the OPP with a duty cycle of 50 %, the OPP may or may
not be triggered. So, the duty cycle at which the OPP is triggered eventually can be set
using a parameter to 11 %, 20 %, 33 %, or 50 %.
OVP protection
In a resonant converter, the voltage at the SUPIC pin reflects the output voltage. When
the SUPIC voltage exceeds a defined level, the OVP protection is triggered. The level
can be set between 1 V and 16 V above the start level in steps of 1 V.
To avoid false triggering, a delay can be set at different values ranging from 10 μs to
800 μs. The response of this protection can be latched, safe restart, or latched after safe
restart. This OVP function can also be disabled.
OVP duty cycle
To minimize the sensitivity of the OVP function, a duty cycle can be set at which the OVP
is eventually triggered. This parameter can be set to 11 %, 20 %, 33 %, or 50 %. If, for
example, the OVP delay is set to 800 μs, the duty cycle to 50 %, and the SUPIC voltage
exceeds the OVP level for 300 μs and drops to below the OVP level for 500 μs, the OVP
is never triggered.
OCP protection
The current in the resonant tank is measured at the SNSCURLLC pin. When the voltage
at this pin exceeds the OCP level, the corresponding switch (GATELS or GATEHS) is
turned off and the system starts the next cycle. So, the LLC current is limited cycle-bycycle.
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Digital configurable LLC and multimode PFC controller
If the OCP occurs for a defined number of cycles, the OCP protection is triggered. The
number of cycles can be set to different values between 5 and 1000.
The response of this protection can be latched, safe restart, or latched after safe restart.
The OCP protection function can also be disabled. However, the LLC current remains
limited cycle-by-cycle.
8.8.5 Power good settings
The power good function gives a prewarning to the load that the converter is switched off
due to disconnected mains or a triggered protection.
Power good time
The power good time is the time between the power good signal indicating that the
converter is about to be switched off and the time the converter eventually stops
switching. This delay can be set to 4 ms, 6 ms, 8 ms, or 10 ms.
Power good at OTP
The power good signal can give a prewarning when the converter is switched off due to
an OTP detection. The OTP can be either an internal or an external OTP.
This function can be enabled or disabled. The delay between the transition of the power
good signal and the moment that the converter stops switching equals the power good
time.
Power good at OPP
The power good signal can give a prewarning when the converter is switched off due
to an OPP detection. The prewarning can be given when the output power exceeds the
OPP level1 or OPP level2 for the defined time.
This function can be enabled or disabled. The delay between the transition of the power
good signal and the moment that the converter stops switching equals the power good
time.
Power good at mains brownout
The power good signal can give a prewarning when the LLC converter is switched off
due to a brownout detection at the mains input of the converter.
This function can be enabled or disabled. The delay between the transition of the power
good signal and the moment that the converter stops switching equals the power good
time.
Power good at LLC brownout level (SNSBOOST)
When the measured voltage at the SNSBOOST pin drops to below the selected
LLC brownout level, the LLC converter stops switching. It normally occurs due to a
disconnected mains.
The power good signal can give a prewarning when the converter is switched off due
to this LLC brownout detection. When the voltage at the SNSBOOST drops to below a
selectable value, the power good feature is triggered. The level can be selected between
1 V and 2.05 V.
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Digital configurable LLC and multimode PFC controller
Power good at OVP (SNSBOOST)
The TEA6017AT offers a setting option to stop the LLC operation at an SNSBOOST
OVP. When the LLC converter is switched off due to an SNSBOOST OVP, the power
good signal can give a prewarning. This function can be enabled or disabled. The delay
between the transition of the power good signal and the moment the converter stops
switching equals the power good time.
Power good ready delay
When the output voltage is in regulation after start-up, power good indicates that the
output voltage is in regulation. A delay can be set between the time the output voltage
reaches the regulation level and the transition of the power good signal. This delay can
be set at different values between 0 s and 1 s.
Power good transition time
The power good function is combined with the feedback network connected at the
SNSFB pin. To avoid that a trigger of the power good function disturbs the regulation
loop, its transition time must have a predefined value. This time can be set at 0.85 ms,
1.8 ms, 2.6 ms, or 3.5 ms.
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Digital configurable LLC and multimode PFC controller
9
Limiting values
Table 5. Limiting values
In accordance with the Absolute Maximum Rating System (IEC 60134).
Symbol
Parameter
Conditions
Min
Max
Unit
VDRAINPFC
voltage on pin
DRAINPFC
during mains
surge t < 0.5 s; 10
times at a 0.1 Hz
interval
−0.4
+685
V
SRDRAINPFC
slew rate on pin
DRAINPFC
−50
+50
V/ns
VSUPIC
voltage on pin
SUPIC
−0.4
+36
V
VSUPHS
voltage on pin
SUPHS
during mains
surge t < 0.5 s; 10
times at a 0.1 Hz
interval
−0.3
+685
V
regarding pin HB
− 0.4
+13
V
Voltages
VGATEHS
voltage on pin
GATEHS
VHB − 0.4
VSUPHS + 0.4
V
VHB
voltage on pin HB during mains
surge; t < 0.5 s;
10 times at a
0.1 Hz interval
−3
+685
V
−13
-
V
−70
+70
V/ns
t < 1 μs
TEA6017AT
Product data sheet
SRHB
slew rate on pin
HB
VGATELS
voltage on pin
GATELS
[1]
−0.4
+14
V
VGATEPFC
voltage on pin
GATEPFC
[1]
−0.4
+14
V
VSNSCAP
voltage on pin
SNSCAP
−0.4
+12
V
VSNSCURLLC
voltage on pin
SNSCURLLC
−0.4
+12
V
VSNSCURPFC
voltage on pin
SNSCURPFC
t < 0.1 s; voltage
at external
series resistance
of 100 Ω,
connected to pin
SNSCURPFC
−18
+12
V
DC; maximum
−0.4
+12
V
VSNSFB
voltage on pin
SNSFB
−0.4
+12
V
VSNSBOOST
voltage on pin
SNSBOOST
−0.4
+12
V
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Digital configurable LLC and multimode PFC controller
Table 5. Limiting values...continued
In accordance with the Absolute Maximum Rating System (IEC 60134).
Symbol
Parameter
VSNSMAINS
voltage on pin
SNSMAINS
Conditions
Min
Max
Unit
−0.4
+12
V
-
0.7
W
General
Ptot
total power
dissipation
Tamb < 75 °C
Tj
junction
temperature
−40
+150
°C
Tstg
storage
temperature
−55
+150
°C
−100
+100
mA
−2000
+2000
V
−1000
+1000
V
Latch-up
Ilu
latch-up current
all pins; according
to JEDEC;
standard 78D
Electrostatic discharge
VESD
electrostatic
human body model
discharge voltage
all pins
charged device
model; all pins
[1]
Although the GATE pins are output pins, the maximum voltage of these pins must not exceed the maximum drive output
voltage by 20 %.
10 Thermal characteristics
Table 6. Thermal characteristics
TEA6017AT
Product data sheet
Symbol
Parameter
Conditions
Typ
Unit
Rth(j-a)
thermal resistance from
junction to ambient
In free air;
JEDEC test board
107
K/W
Rth(j-c)
thermal resistance from
junction to case
In free air;
JEDEC test board
60
K/W
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Digital configurable LLC and multimode PFC controller
11 Characteristics
Table 7. Characteristics
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
Ioff(DRAINPFC)
off-state current on pin
DRAINPFC
VDRAINPFC = 400 V;
VSUPIC = 19 V
2
5
8
μA
VDRAINPFC
voltage on pin DRAINPFC
VSUPIC = 19 V;
IDRAINPFC = 3 mA
22
26
30
V
Ich(SUPIC)
charge current on pin SUPIC
VDRAINPFC = 50 ;
VSUPIC = 19 V
−10
−6.5
−3
mA
DRAINPFC pin
SUPIC pin
Vstart(SUPIC)
start voltage on pin SUPIC
18.2
19.0
19.7
V
Vstart(hys)SUPIC
start voltage hysteresis on pin
SUPIC
−0.9
−0.7
−0.5
V
Vlow(hys)SUPIC
low voltage hysteresis on pin
SUPIC
0.5
0.7
0.9
V
Vlow(SUPIC)
low voltage on pin SUPIC
11.5
12.0
12.5
V
Vuvp(SUPIC)
undervoltage protection
voltage on pin SUPIC
9.6
10.0
10.4
V
Δ(vlow-vuvp)SUPIC
low voltage to undervoltage
protection voltage difference
on pin SUPIC
1.7
2.0
2.3
V
Vrst(SUPIC)
reset voltage on pin SUPIC
[1]
8.6
9.0
9.4
V
supply current on pin SUPIC
non-operating mode;
Isnsfb = −100 μA;
Isnscap = −100 μA
[2]
700
890
1100
μA
operating mode;
fHB = 100 kHz; Isnsfb = −80 μA;
Isnscap = −100 μA; driver pins
open
[2]
6
8
10
mA
ICC(SUPIC)
Vlow − Vuvp
Output overvoltage protection
VO(ovp)SUPIC
output overvoltage protection
voltage on pin SUPIC
27.9
28.7
29.5
V
td(ovp)SUPIC
overvoltage protection delay
time on pin SUPIC
45
50
55
μs
Mains voltage sensing (SNSMAINS pin)
Iclamp(max)
maximum clamp current
VSNSMAINS = 9.5 V
2.5
3.5
4.5
mA
II(lim)SNSMAINS
limiting input current on pin
SNSMAINS
SNSMAINS limit measuring
input current
17.2
18.6
20.0
μA
Ibi
brownin current
5.3
5.5
5.7
μA
Ibo
brownout current
4.6
4.8
5.0
μA
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Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
Ibo(hys)
hysteresis of brownout
current
Ibi − Ibo
0.66
0.73
0.80
μA
td(det)bo
brownout detection delay time PFC
45
50
55
ms
225
250
275
ms
LLC
External overtemperature measurement
Io(SNSMAINS)
output current on pin
SNSMAINS
−645
−600
−565
μA
tdet(max)NTC
NTC maximum detection time
45
50
55
μs
Vdet(SNSMAINS)
detection voltage on pin
SNSMAINS
2.89
3.08
3.27
V
td(otp)
overtemperature protection
delay time
3.6
4.0
4.4
s
180
200
220
ms
NTC measurement;
ISNSMAINS = −600 μA
X-capacitor discharge
td(dch)
discharge delay time
SNSCURPFC pin
Io(min)SNSCURPFC
minimum output current on
pin SNSCURPFC
for open pin protection;
VSNSCURPFC = 500 mV
−0.8
−0.6
−0.4
μA
Vdet(SNSCURPFC)
detection voltage on pin
SNSCURPFC
open pin detection level
190
235
280
mV
Vdet(demag)
demagnetization detection
voltage
−15
−10
−5
mV
Vocp(PFC)
PFC overcurrent protection
voltage
−320
−300
−275
mV
td(swoff)driver
driver switch-off delay time
300
375
450
ns
−50
-
-
V/μs
9
15
21
V
dV/dt ≤ −0.5 V/μs
Valley sensing (DRAINPFC pin)
ΔVdet(min)/Δt
minimum slope detection
voltage
ΔVdet(min)
minimum detection voltage
change
tto(vrec)
valley recognition time-out
time
6.3
7.0
7.7
μs
PFC minimum off-time
0.45
0.50
0.55
μs
ringing frequency = 1 MHz
PFC
PFC timing
toff(PFC)min
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Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
soft start time
23
25
28
ms
fsw(PFC)min
minimum PFC switching
frequency
36
40
44
kHz
fsw(PFC)max
maximum PFC switching
frequency
67
75
83
kHz
PFC start-up soft-start time
tstart(soft)
PFC frequency
GATEPFC pin
Isource(peak)
source peak current
Cload = 4.7 nF; VSUPIC ≥ 13 V
[2]
−1.1
−0.9
−0.7
A
[2]
0.7
1.0
1.3
A
Isink(peak)
sink peak current
Cload = 4.7 nF; VSUPIC ≥ 13 V
ROH(GATEPFC)
HIGH-level output resistance
on pin GATEPFC
IGATEPFC = −30 mA;
VSUPIC = 14.5 V
8
14
20
Ω
ROL(GATEPFC)
LOW-level output resistance
on pin GATEPFC
IGATEPFC = 30 mA;
VSUPIC = 14.5 V
3
4.5
6
Ω
VOH(GATEPFC)
HIGH-level output voltage on
pin GATEPFC
VSUPIC ≥ 14.5 V; fsw = 50 kHz;
Iload = 0
[2]
11.5
12.3
13.1
V
VSUPIC = 9.5 V; fsw = 50 kHz;
Iload = 0
[2]
9.45
9.5
9.55
V
0.10
0.17
0.24
V
VOL(GATEPFC)
LOW-level output voltage on
pin GATEPFC
IGATEPFC = 40 mA;
VSUPIC ≥ 14.5 V
tr(GATEPFC)
rise time on pin GATEPFC
1 V to 9 V; VSUPIC = 13 V;
1 nF load
[2]
10
15
20
ns
tf(GATEPFC)
fall time on pin GATEPFC
9 V to 1 V; VSUPIC = 13 V;
1 nF load
[2]
10
15
20
ns
Ipd(SNSBOOST)
pull-down current on pin
SNSBOOST
at VSNSBOOST = Vscp(stop)
25
50
75
nA
Vreg(SNSBOOST)
regulation voltage on pin
SNSBOOST
2.475
2.500
2.525
V
Vstop(ovp)PFC
PFC overvoltage protection
stop voltage
2.59
2.63
2.67
V
Vprot(ovp)PFC
PFC overvoltage protection
protection voltage
via pin DRAINPFC
450
475
500
V
tleb(ovp)PFC
PFC overvoltage protection
leading-edge blanking time
via pin DRAINPFC
360
400
440
ns
SNSBOOST pin
PFC part
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Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
LLC part
Vuvp(SNSBOOST)
undervoltage protection
voltage on pin SNSBOOST
1.60
1.65
1.70
V
Vstart(SNSBOOST)
start voltage on pin
SNSBOOST
2.23
2.30
2.37
V
Vdet(SNSBOOST)
detection voltage on pin
SNSBOOST
Power good detection voltage
1.715
1.750
1.785
V
ΔVreg-det
voltage difference between
regulation and detection
pin SNSBOOST; indication of
the power good delay
0.72
0.75
0.78
V
Fast disable function
Vscp(stop)
stop short-circuit protection
voltage
0.37
0.39
0.41
V
Vscp(start)
start short-circuit protection
voltage
0.40
0.45
0.50
V
tfltr(scp)
short-circuit protection filter
time
4
10
15
μs
2.44
2.50
2.56
V
−245
−210
−175
μA
SNSCAP voltage range for
the high-side comparator,
Vhs(SNSCAP).
2.35
-
4.50
V
SNSCAP voltage range for
the low-side comparator,
Vls(SNSCAP).
0.50
-
2.65
V
SNSCAP pin
VAV(regd)SNSCAP
regulated average voltage on
pin SNSCAP
Ibias(max)SNSCAP
maximum bias current on pin
SNSCAP
Vrange(SNSCAP)
voltage range on pin
SNSCAP
regulated average of
Vhs(SNSCAP) and Vls(SNSCAP)
Vacc
voltage accuracy
SNSCAP comparator voltage
accuracy
−10
-
+10
mV
ΔVth(SNSCAP)
threshold voltage difference
on pin SNSCAP
Vhs(SNSCAP) − Vls(SNSCAP);
Pout = 200 %;
VSNSBOOST < 1.9 V
3.12
3.27
3.42
V
Vhs(SNSCAP) − Vls(SNSCAP);
Pout = 100 %;
VSNSBOOST = 2.5 V
0.93
1.01
1.09
V
delay between exceeding
Vcaph/Vcapl and driver off;
dV/dt = 0.1 V/μs
-
-
125
ns
2.4
2.5
2.6
V
td
delay time
SNSCURLLC pin
Vbias(SNSCURLLC)
TEA6017AT
Product data sheet
bias voltage on pin
SNSCURLLC
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Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
RO(SNSCURLLC)
Min
Typ
Max
Unit
output resistance on pin
SNSCURLLC
45
55
65
kΩ
Vlmtr(ocp)
overcurrent protection voltage soft-start overcurrent limiter
limiter
0.66
0.75
0.83
V
Vocp(LLC)
LLC overcurrent protection
voltage
positive level
VSNSCURLLC − Vbias(SNSCURLLC)
1.35
1.50
1.65
V
negative level
VSNSCURLLC − Vbias(SNSCURLLC)
−1.65
−1.50
−1.35
V
positive level
VSNSCURLLC − Vbias(SNSCURLLC)
83
100
115
mV
negative level
VSNSCURLLC − Vbias(SNSCURLLC)
−115
−100
−83
mV
detected as ≥ 0
−16
−11
−6
mV
detected as ≤ 0
6
11
16
mV
Vreg(capm)
Vdet(zero)
Conditions
capacitive mode regulation
level
zero detection voltage
SNSFB pin
Vlow(SNSFB)
low voltage on pin SNSFB
indicating iPowerGood = '1';
0 μA < Iopto < 3.5 mA.
0.43
0.50
0.57
V
Vhigh(SNSFB)
high voltage on pin SNSFB
indicating iPowerGood = '0';
0 μA < Iopto < 3.5 mA.
3.3
3.5
3.8
V
tt(powergood)
power good transition time
1.5
1.8
2.0
ms
regulation current on pin
SNSFB
−90
−80
−70
μA
−110
−100
−90
μA
Optobias regulator
Ireg(SNSFB)
Burst mode regulator
Istart(burst)
burst mode start current
LLC burst mode
Istop(burst)
burst mode stop current
−220
−200
−180
μA
fburst(max)
maximum burst mode
frequency
720
800
880
Hz
δen(burst)
burst mode duty cycle enable enable of PFC burst mode;
49
duty cycle of LLC burst mode;
duty cycle = measured LLC burston time / set LLC burst period
50
51
%
Ncy(en)burst
burst mode enable number of enable of PFC burst mode;
16
cycles
duty cycle of LLC burst mode;
duty cycle = measured LLC burston time / set LLC burst period
16
16
-
δdis(burst)
burst mode disable duty cycle disable of PFC burst mode;
74
duty cycle of LLC burst mode;
duty cycle = measured LLC burston time / set LLC burst period
75
76
%
Burst mode
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Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
td(burst)exit
burst-mode exit delay time
Min
Typ
Max
Unit
3.6
4
4.4
ms
delay power good after output
voltage ready
4.5
5.0
5.5
ms
power good delay before
protection
3.6
4.0
4.4
ms
Power good characteristics (pin SNSFB)
td(powergood)
power good delay time
LLC timing
ton(min)LLC
LLC minimum on-time
1105
1230
1355
ns
ton(max)LLC
LLC maximum on-time
18
20
22
μs
90
100
110
ms
Overpower protection
tstartup(max)
maximum start-up time
td(opp)
overpower protection delay
time
OPP 1
45
50
55
ms
ΔVdet(min)/Δt
minimum slope detection
voltage
positive and negative
minimum slope detection
level.
-
-
120
V/μs
ΔVdet(max)/Δt
maximum slope detection
voltage
positive and negative
maximum slope detection
level.
50
-
-
V/ns
tno(min)
minimum non-overlap time
200
230
260
ns
tno(max)
maximum non-overlap time
0.99
1.10
1.21
μs
HB pin
GATELS pin
Isource(peak)
source peak current
Cload = 4.7 nF; VSUPIC ≥ 13 V
[2]
−1.1
−0.9
−0.7
A
[2]
0.7
1.0
1.3
A
Isink(peak)
sink peak current
Cload = 4.7 nF; VSUPIC ≥ 13 V
ROH(GATELS)
HIGH-level output resistance
on pin GATELS
IGATELS = −30 mA;
VSUPIC = 14.5 V
8
14
20
Ω
ROL(GATELS)
LOW-level output resistance
n pin GATELS
IGATELS = 30 mA;
VSUPIC = 14.5 V
3
4.5
6
Ω
VOH(GATELS)
HIGH-level output voltage on
pin GATELS
fsw = 100 kHz; Iload = 0;
VSUPIC ≥ 14.5 V
[2]
11.5
12.3
13.1
V
fsw = 100 kHz; Iload = 0;
VSUPIC = 9.5 V
[2]
9.45
9.5
9.55
V
0.10
0.17
0.24
V
VOL(GATELS)
LOW-level output voltage on
pin GATELS
IGATELS = 40 mA;
VSUPIC ≥ 14.5 V
tr(GATELS)
rise time on pin GATELS
1 V to 9 V; VSUPIC = 13 V;
1 nF load
[2]
10
15
20
ns
tf(GATELS)
fall time on pin GATELS
9 V to 1 V; VSUPIC = 13 V;
1 nF load
[2]
10
15
20
ns
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NXP Semiconductors
Digital configurable LLC and multimode PFC controller
Table 7. Characteristics...continued
Tamb = 25 °C; VSUPIC = 19.5 V; all voltages are measured with respect to GND; currents are positive when flowing into the
IC; unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
Isource(peak)
source peak current
Cload = 4.7 nF;
VSUPHS − VHB = 12 V
[2]
−0.8
−0.6
−0.4
A
Isink(peak)
sink peak current
Cload = 4.7 nF;
VSUPHS − VHB = 12 V
[2]
0.8
1.1
1.4
A
ROH(GATEHS)
HIGH-level output resistance
on pin GATEHS
IGATEHS = −30 mA;
VSUPHS − VHB = 12 V
6
10
14
Ω
ROL(GATEHS)
LOW-level output resistance
on pin GATEHS
IGATEHS = 30 mA;
VSUPHS − VHB = 12 V
3
5
7
Ω
VOH(GATEHS)
HIGH-level output voltage on
pin GATEHS
fsw = 100 kHz; Iload = 0;
VSUPHS − VHB= 12 V
11.5
12
12.5
V
VOL(GATEHS)
LOW-level output voltage on
pin GATEHS
IGATEHS = 40 mA;
VSUPHS − VHB = 12 V
0.1
0.2
0.3
V
tr(GATEHS)
rise time on pin GATEHS
1 V to 9 V;
VSUPHS − VHB = 11 V;
1 nF load
[2]
15
25
35
ns
tf(GATEHS)
fall time on pin GATEHS
9 V to 1 V;
VSUPHS − VHB = 11 V;
1 nF load
[2]
10
15
20
ns
reset voltage on pin SUPHS
+25 °C < T < 125 °C
5.5
7.2
8.2
V
GATEHS pin
[2]
SUPHS pin
Vrst(SUPHS)
System protection
td(restart)
restart delay time
0.9
1.0
1.1
s
td(flr)
fast latch reset delay time
45
50
55
ms
VIL
LOW-level input voltage
0
-
0.8
V
VIH
HIGH-level input voltage
1.4
-
5.0
V
6.8
-
-
mA
120
135
150
°C
2
I C communication
Ipd(SNSCAP)
pull-down current on pin
SNSCAP
To ensure proper operation,
the external pull-up must
always be lower than 6.8 mA.
[3]
Overtemperature protection
Totp
[1]
[2]
[3]
overtemperature protection
trip
The Vuvp(SUPIC) and Vrst(SUPIC) overlap. When SUPIC drops to below the Vuvp(SUPIC), a general reset may follow.
Covered by correlating measurement
As the minimum limit determines the application design, the maximum limit is not relevant.
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Digital configurable LLC and multimode PFC controller
12 Application information
Mains-L
Vboost
~
Mains-N
GATELS
SUPIC
SUPHS
fast
disable
SNSBOOST
CSUPHS
GATEHS
S2
D2
Vout (DC)
LS
HB
LM
GATELS
S1
D1
powergood
DRAINPFC
GATEPFC
RSNSCUR
IC
fast disable
SNSCAP
SNSCURPFC
CR
RSENSE
SNSCURLLC
SNSMAINS
GND
SUPIC
SUPIC
CSUPIC
powergood
SNSFB
aaa-039100
Figure 29. Application diagram
TEA6017AT
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Digital configurable LLC and multimode PFC controller
13 Package outline
SO16: plastic small outline package; 16 leads; body width 3.9 mm
SOT109-1
D
E
A
X
c
y
HE
v M A
Z
16
9
Q
A2
A
(A 3)
A1
pin 1 index
θ
Lp
1
L
8
e
w M
bp
0
2.5
detail X
5 mm
scale
DIMENSIONS (inch dimensions are derived from the original mm dimensions)
UNIT
A
max.
A1
A2
A3
bp
c
D (1)
E (1)
e
HE
L
Lp
Q
v
w
y
Z (1)
mm
1.75
0.25
0.10
1.45
1.25
0.25
0.49
0.36
0.25
0.19
10.0
9.8
4.0
3.8
1.27
6.2
5.8
1.05
1.0
0.4
0.7
0.6
0.25
0.25
0.1
0.7
0.3
inches
0.069
0.010 0.057
0.004 0.049
0.01
0.019 0.0100 0.39
0.014 0.0075 0.38
0.16
0.15
0.05
0.039
0.016
0.028
0.020
0.01
0.01
0.004
0.028
0.012
0.244
0.041
0.228
θ
o
8
o
0
Note
1. Plastic or metal protrusions of 0.15 mm (0.006 inch) maximum per side are not included.
REFERENCES
OUTLINE
VERSION
IEC
JEDEC
SOT109-1
076E07
MS-012
JEITA
EUROPEAN
PROJECTION
ISSUE DATE
99-12-27
03-02-19
Figure 30. Package outline SOT109-1 (SO16)
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Digital configurable LLC and multimode PFC controller
14 Appendix: Ringo parameter settings
A table containing the Ringo parameter settings/IC parameter settings is available in the
TEA6017AT data sheet addendum. The data sheet addendum can be requested from
NXP Semiconductors.
TEA6017AT
Product data sheet
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NXP Semiconductors
Digital configurable LLC and multimode PFC controller
15 Revision history
Table 8. Revision history
Document ID
Release date
Data sheet status
Change notice
Supersedes
TEA6017AT v.1
20220311
Product data sheet
-
-
TEA6017AT
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Digital configurable LLC and multimode PFC controller
16 Legal information
16.1 Data sheet status
Document status
[1][2]
Product status
[3]
Definition
Objective [short] data sheet
Development
This document contains data from the objective specification for product
development.
Preliminary [short] data sheet
Qualification
This document contains data from the preliminary specification.
Product [short] data sheet
Production
This document contains the product specification.
[1]
[2]
[3]
Please consult the most recently issued document before initiating or completing a design.
The term 'short data sheet' is explained in section "Definitions".
The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple
devices. The latest product status information is available on the Internet at URL http://www.nxp.com.
16.2 Definitions
Draft — A draft status on a document indicates that the content is still
under internal review and subject to formal approval, which may result
in modifications or additions. NXP Semiconductors does not give any
representations or warranties as to the accuracy or completeness of
information included in a draft version of a document and shall have no
liability for the consequences of use of such information.
Short data sheet — A short data sheet is an extract from a full data sheet
with the same product type number(s) and title. A short data sheet is
intended for quick reference only and should not be relied upon to contain
detailed and full information. For detailed and full information see the
relevant full data sheet, which is available on request via the local NXP
Semiconductors sales office. In case of any inconsistency or conflict with the
short data sheet, the full data sheet shall prevail.
Product specification — The information and data provided in a Product
data sheet shall define the specification of the product as agreed between
NXP Semiconductors and its customer, unless NXP Semiconductors and
customer have explicitly agreed otherwise in writing. In no event however,
shall an agreement be valid in which the NXP Semiconductors product
is deemed to offer functions and qualities beyond those described in the
Product data sheet.
16.3 Disclaimers
Limited warranty and liability — Information in this document is believed
to be accurate and reliable. However, NXP Semiconductors does not give
any representations or warranties, expressed or implied, as to the accuracy
or completeness of such information and shall have no liability for the
consequences of use of such information. NXP Semiconductors takes no
responsibility for the content in this document if provided by an information
source outside of NXP Semiconductors.
In no event shall NXP Semiconductors be liable for any indirect, incidental,
punitive, special or consequential damages (including - without limitation lost profits, lost savings, business interruption, costs related to the removal
or replacement of any products or rework charges) whether or not such
damages are based on tort (including negligence), warranty, breach of
contract or any other legal theory.
Notwithstanding any damages that customer might incur for any reason
whatsoever, NXP Semiconductors’ aggregate and cumulative liability
towards customer for the products described herein shall be limited in
accordance with the Terms and conditions of commercial sale of NXP
Semiconductors.
Right to make changes — NXP Semiconductors reserves the right to
make changes to information published in this document, including without
limitation specifications and product descriptions, at any time and without
notice. This document supersedes and replaces all information supplied prior
to the publication hereof.
TEA6017AT
Product data sheet
Suitability for use — NXP Semiconductors products are not designed,
authorized or warranted to be suitable for use in life support, life-critical or
safety-critical systems or equipment, nor in applications where failure or
malfunction of an NXP Semiconductors product can reasonably be expected
to result in personal injury, death or severe property or environmental
damage. NXP Semiconductors and its suppliers accept no liability for
inclusion and/or use of NXP Semiconductors products in such equipment or
applications and therefore such inclusion and/or use is at the customer’s own
risk.
Applications — Applications that are described herein for any of these
products are for illustrative purposes only. NXP Semiconductors makes no
representation or warranty that such applications will be suitable for the
specified use without further testing or modification.
Customers are responsible for the design and operation of their
applications and products using NXP Semiconductors products, and NXP
Semiconductors accepts no liability for any assistance with applications or
customer product design. It is customer’s sole responsibility to determine
whether the NXP Semiconductors product is suitable and fit for the
customer’s applications and products planned, as well as for the planned
application and use of customer’s third party customer(s). Customers should
provide appropriate design and operating safeguards to minimize the risks
associated with their applications and products.
NXP Semiconductors does not accept any liability related to any default,
damage, costs or problem which is based on any weakness or default
in the customer’s applications or products, or the application or use by
customer’s third party customer(s). Customer is responsible for doing all
necessary testing for the customer’s applications and products using NXP
Semiconductors products in order to avoid a default of the applications
and the products or of the application or use by customer’s third party
customer(s). NXP does not accept any liability in this respect.
Limiting values — Stress above one or more limiting values (as defined in
the Absolute Maximum Ratings System of IEC 60134) will cause permanent
damage to the device. Limiting values are stress ratings only and (proper)
operation of the device at these or any other conditions above those
given in the Recommended operating conditions section (if present) or the
Characteristics sections of this document is not warranted. Constant or
repeated exposure to limiting values will permanently and irreversibly affect
the quality and reliability of the device.
Terms and conditions of commercial sale — NXP Semiconductors
products are sold subject to the general terms and conditions of commercial
sale, as published at http://www.nxp.com/profile/terms, unless otherwise
agreed in a valid written individual agreement. In case an individual
agreement is concluded only the terms and conditions of the respective
agreement shall apply. NXP Semiconductors hereby expressly objects to
applying the customer’s general terms and conditions with regard to the
purchase of NXP Semiconductors products by customer.
No offer to sell or license — Nothing in this document may be interpreted
or construed as an offer to sell products that is open for acceptance or
the grant, conveyance or implication of any license under any copyrights,
patents or other industrial or intellectual property rights.
All information provided in this document is subject to legal disclaimers.
Rev. 1 — 11 March 2022
© NXP B.V. 2022. All rights reserved.
61 / 63
�TEA6017AT
NXP Semiconductors
Digital configurable LLC and multimode PFC controller
Quick reference data — The Quick reference data is an extract of the
product data given in the Limiting values and Characteristics sections of this
document, and as such is not complete, exhaustive or legally binding.
Export control — This document as well as the item(s) described herein
may be subject to export control regulations. Export might require a prior
authorization from competent authorities.
Suitability for use in non-automotive qualified products — Unless
this data sheet expressly states that this specific NXP Semiconductors
product is automotive qualified, the product is not suitable for automotive
use. It is neither qualified nor tested in accordance with automotive testing
or application requirements. NXP Semiconductors accepts no liability for
inclusion and/or use of non-automotive qualified products in automotive
equipment or applications.
In the event that customer uses the product for design-in and use in
automotive applications to automotive specifications and standards,
customer (a) shall use the product without NXP Semiconductors’ warranty
of the product for such automotive applications, use and specifications, and
(b) whenever customer uses the product for automotive applications beyond
NXP Semiconductors’ specifications such use shall be solely at customer’s
own risk, and (c) customer fully indemnifies NXP Semiconductors for any
liability, damages or failed product claims resulting from customer design and
use of the product for automotive applications beyond NXP Semiconductors’
standard warranty and NXP Semiconductors’ product specifications.
Translations — A non-English (translated) version of a document is for
reference only. The English version shall prevail in case of any discrepancy
between the translated and English versions.
TEA6017AT
Product data sheet
Security — Customer understands that all NXP products may be subject to
unidentified vulnerabilities or may support established security standards or
specifications with known limitations. Customer is responsible for the design
and operation of its applications and products throughout their lifecycles
to reduce the effect of these vulnerabilities on customer’s applications
and products. Customer’s responsibility also extends to other open and/or
proprietary technologies supported by NXP products for use in customer’s
applications. NXP accepts no liability for any vulnerability. Customer should
regularly check security updates from NXP and follow up appropriately.
Customer shall select products with security features that best meet rules,
regulations, and standards of the intended application and make the
ultimate design decisions regarding its products and is solely responsible
for compliance with all legal, regulatory, and security related requirements
concerning its products, regardless of any information or support that may be
provided by NXP.
NXP has a Product Security Incident Response Team (PSIRT) (reachable
at PSIRT@nxp.com) that manages the investigation, reporting, and solution
release to security vulnerabilities of NXP products.
16.4 Trademarks
Notice: All referenced brands, product names, service names, and
trademarks are the property of their respective owners.
NXP — wordmark and logo are trademarks of NXP B.V.
GreenChip — is a trademark of NXP B.V.
All information provided in this document is subject to legal disclaimers.
Rev. 1 — 11 March 2022
© NXP B.V. 2022. All rights reserved.
62 / 63
�TEA6017AT
NXP Semiconductors
Digital configurable LLC and multimode PFC controller
Contents
1
2
2.1
2.2
2.3
3
4
5
6
7
7.1
7.2
8
8.1
8.1.1
8.1.2
8.2
8.2.1
8.2.2
8.3
8.3.1
8.3.2
8.3.3
8.3.3.1
8.3.3.2
8.3.3.3
8.3.3.4
8.4
8.5
8.5.1
8.5.2
8.5.3
8.5.4
8.5.5
8.5.6
8.5.7
8.5.8
8.5.9
8.5.10
8.5.11
8.5.12
8.5.13
8.6
8.6.1
8.6.2
8.6.3
8.6.4
8.6.5
8.6.6
8.6.7
General description ............................................ 1
Features and benefits .........................................2
Distinctive features ............................................ 2
Green features ...................................................2
Protection features .............................................3
Applications .........................................................3
Ordering information .......................................... 3
Marking .................................................................3
Block diagram ..................................................... 4
Pinning information ............................................ 5
Pinning ............................................................... 5
Pin description ................................................... 5
Functional description ........................................7
Supply voltages ................................................. 7
Start-up and supply voltage ...............................7
High-side driver floating supply (SUPHS
pin) ..................................................................... 9
LLC system regulation .....................................10
Output power regulation loop .......................... 11
Output voltage start-up .................................... 12
Modes of operation ..........................................13
High-power mode ............................................ 14
Low-power mode ............................................. 15
Burst mode ...................................................... 17
Frequency regulation ....................................... 18
Negative transient response ............................ 18
Burst-mode delay function ............................... 19
Burst-mode exit delay function ........................ 20
Optobias regulation ..........................................20
Power factor correction (PFC) regulation .........21
PFC switching frequency .................................23
Frequency jitter ................................................ 24
Multimode operation (DCM/QR/CCM) ............. 24
DCM/QR mode of operation ............................ 24
Fixed-frequency CCM mode ............................24
PFC start-up .................................................... 25
Output voltage regulation ................................ 25
PFC burst mode .............................................. 25
PFC burst mode soft start/soft stop ................. 26
Valley switching and demagnetization ............. 26
Frequency limitation .........................................26
Mains voltage compensation (SNSMAINS
pin) ................................................................... 27
Active X-capacitor discharge ........................... 27
Protections ....................................................... 27
Undervoltage protection SUPIC .......................29
MTP fail ........................................................... 29
Internal overtemperature protection (OTP) ...... 29
Brownin/brownout and external
overtemperature protection ..............................30
Short-circuit protection/fast disable ..................31
Brownout mains ............................................... 31
Overvoltage protection (SNSBOOST pin) ........31
8.6.8
8.6.9
8.6.10
8.6.11
8.6.12
8.6.13
8.6.14
8.6.15
8.6.16
8.6.17
8.6.18
8.6.19
8.7
8.8
8.8.1
8.8.1.1
8.8.1.2
8.8.1.3
8.8.1.4
8.8.1.5
8.8.1.6
8.8.2
8.8.2.1
8.8.2.2
8.8.2.3
8.8.2.4
8.8.2.5
8.8.2.6
8.8.2.7
8.8.2.8
8.8.3
8.8.3.1
8.8.3.2
8.8.3.3
8.8.3.4
8.8.3.5
8.8.4
8.8.4.1
8.8.4.2
8.8.4.3
8.8.5
9
10
11
12
13
14
15
16
Overvoltage protection (DRAINPFC pin) ......... 31
Overcurrent protection, inrush protection
(SNSCURPFC pin) .......................................... 32
PFC coil short protection (SNSCURPFC
pin) ................................................................... 32
Undervoltage protection SUPHS ..................... 32
Undervoltage protection boost .........................32
Overvoltage protection .....................................32
Capacitive mode regulation (CMR) ..................32
Overcurrent protection ..................................... 34
Maximum start-up time .................................... 34
Overpower protection ...................................... 34
Latched, safe restart, or latched after safe
restart ...............................................................35
Fast latch reset ................................................35
Power good function ........................................36
Settings ............................................................ 37
General settings .............................................. 37
Protection register ............................................37
Supply start level ............................................. 37
Read lock .........................................................37
Write lock .........................................................37
Reset to the default values ..............................37
Customer MTP code ........................................37
PFC settings .................................................... 38
Soft-start time .................................................. 38
Active X-capacitor discharge ........................... 38
Mains measurement impedance ......................38
Number of mains resistors .............................. 38
PFC mode of operation ................................... 38
PFC minimum and maximum frequency ..........38
Burst mode: Output voltage ripple ................... 38
Burst mode: Soft-start/soft-stop time ............... 39
LLC settings .....................................................39
LLC disable ......................................................39
Start-up ............................................................ 39
LLC switching .................................................. 39
Feedback ......................................................... 40
Operation modes ............................................. 40
Protection settings ........................................... 42
General protections ......................................... 42
PFC general protections ..................................43
LLC general protections .................................. 44
Power good settings ........................................ 46
Limiting values .................................................. 48
Thermal characteristics ....................................49
Characteristics .................................................. 50
Application information .................................... 57
Package outline .................................................58
Appendix: Ringo parameter settings .............. 59
Revision history ................................................ 60
Legal information .............................................. 61
Please be aware that important notices concerning this document and the product(s)
described herein, have been included in section 'Legal information'.
© NXP B.V. 2022.
All rights reserved.
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
Date of release: 11 March 2022
Document identifier: TEA6017AT
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