MARVELL 88EM8041XX-SAG2C000-T

Cover
88EM8040/88EM8041
Power Factor Correction Controller for
Flyback Topology
Datasheet
Customer Use Only
Doc. No. MV-S104983-01, Rev. A
October 5, 2009
Marvell. Moving Forward Faster
Document Classification: Proprietary
88EM8040/88EM8041
Datasheet
Document Conventions
Note: Provides related information or information of special importance.
Caution: Indicates potential damage to hardware or software, or loss of data.
Warning: Indicates a risk of personal injury.
Document Status
Doc Status: Preliminary
Technical Publication: 0.xx
For more information, visit our website at: www.marvell.com
Disclaimer
No part of this document may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, for any purpose,
without the express written permission of Marvell. Marvell retains the right to make changes to this document at any time, without notice. Marvell makes no warranty of any
kind, expressed or implied, with regard to any information contained in this document, including, but not limited to, the implied warranties of merchantability or fitness for any
particular purpose. Further, Marvell does not warrant the accuracy or completeness of the information, text, graphics, or other items contained within this document.
Marvell products are not designed for use in life-support equipment or applications that would cause a life-threatening situation if any such products failed. Do not use
Marvell products in these types of equipment or applications.
With respect to the products described herein, the user or recipient, in the absence of appropriate U.S. government authorization, agrees:
1) Not to re-export or release any such information consisting of technology, software or source code controlled for national security reasons by the U.S. Export Control
Regulations ("EAR"), to a national of EAR Country Groups D:1 or E:2;
2) Not to export the direct product of such technology or such software, to EAR Country Groups D:1 or E:2, if such technology or software and direct products thereof are
controlled for national security reasons by the EAR; and,
3) In the case of technology controlled for national security reasons under the EAR where the direct product of the technology is a complete plant or component of a plant,
not to export to EAR Country Groups D:1 or E:2 the direct product of the plant or major component thereof, if such direct product is controlled for national security reasons
by the EAR, or is subject to controls under the U.S. Munitions List ("USML").
At all times hereunder, the recipient of any such information agrees that they shall be deemed to have manually signed this document in connection with their receipt of any
such information.
Copyright © 1999–2009. Marvell International Ltd. All rights reserved. Marvell, Moving Forward Faster, the Marvell logo, Alaska, AnyVoltage, DSP Switcher, Fastwriter,
Feroceon, Libertas, Link Street, PHYAdvantage, Prestera, TopDog, Virtual Cable Tester, Yukon, and ZJ are registered trademarks of Marvell or its affiliates. CarrierSpan,
LinkCrypt, Powered by Marvell Green PFC, Qdeo, QuietVideo, Sheeva, TwinD, and VCT are trademarks of Marvell or its affiliates.
Patent(s) Pending—Products identified in this document may be covered by one or more Marvell patents and/or patent applications.
Doc. No. MV-S104983-01 Rev. A
Page 2
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
88EM8040/88EM8041
Power Factor Correction Controller for Flyback Topology
Datasheet
PRODUCT OVERVIEW
The Marvell® 88EM8040/88EM8041 device is a high
performance Power Factor Correction (PFC) Controller for
flyback applications. Both devices work at fixed frequencies,
88EM8040 at 60kHz while 88EM8041 at 120kHz. It can be used
in a wide variety of universal input PFC flyback converters with
an output power range of up to 150W without using any external
driver.
General Features
„
Patented DSP control with adaptive loop coefficient
Continuous Conduction Mode (CCM) operation
Average current mode control
Adaptive control loop achieves high power factor for a
wide range of voltage and load conditions
Adaptive over current protection for universal voltage
Fixed frequency of operation
High power factor and low harmonic distortion for a wide
range of load conditions
Up to 2A driver capability
Minimal external components required
Under voltage lockout (UVLO)
Over voltage protection (OVP)
Thermal shutdown
Input line frequency range from 45Hz to 65Hz
„
„
„
„
Marvell advanced mixed signal technology ensures the lowest
Total Harmonic Distortion (THD) in the industry. The IC operates
under average Continuous Conduction Mode (CCM).
„
„
The 88EM8040/88EM8041 PFC controller improves the steady
state and transient performance through Marvell's innovative
Digital Signal Processing (DSP) solution. The proprietary
adaptive over-current protection has the ability to ensure almost
constant power constraint and provides safety provisions
including open loop and over voltage protection protocols.
„
„
„
„
„
„
The internal voltage loop compensation and current loop control
guarantees system stability and thus reduces the external
component count and costs.
Applications
„
Universal input PFC flyback converters
AC/DC adaptors and battery charger
„
The 8-pin SOIC package further facilitates the application
design process, saving board space. The resultant simple
system design and minimum cost makes 88EM8040/88EM8041
the ideal choice for any flyback application with PFC.
Figure 1: PFC Flyback Circuit Diagram
DR2
V DCin
Bridge
Retifier
diode
PFC
C in
Np
Csn
Rsn
R gate
R sen
Load
C O2
Dsn
AC
IN
Vout
N S2
Drain
Q1
Rcs
Ra
Rb
Rc
OCP SW SGND
Ccs
88EM8040/
8041
ISNS
VIN
R S1
PGND
R S4
C S2
VDD
FB
R S2
C S1 R S5
Opto-Coupler
CVDD
R f1
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Vref
R S3
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 3
88EM8040/88EM8041
Datasheet
THIS PAGE INTENTIONALLY LEFT BLANK
Doc. No. MV-S104983-01 Rev. A
Page 4
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Table of Contents
Table of Contents
Table of Contents ....................................................................................................................................... 5
List of Figures............................................................................................................................................. 7
List of Tables .............................................................................................................................................. 9
1
Signal Description ....................................................................................................................... 11
1.1
Pin Configurations ...........................................................................................................................................11
1.2
Pin Descriptions ..............................................................................................................................................11
2
Electrical Specifications ............................................................................................................. 13
2.1
Absolute Maximum Ratings ...........................................................................................................................13
2.2
Recommended Operating Conditions .............................................................................................................14
2.3
Electrical Characteristics ................................................................................................................................15
3
Functional Description................................................................................................................ 19
3.1
Overview .........................................................................................................................................................19
3.2
Signal Process and Functions.........................................................................................................................20
4
Functional Characteristics ......................................................................................................... 21
4.1
VDD Characteristics ........................................................................................................................................21
4.2
VFB Characteristics for Over Voltage Protection .............................................................................................23
4.3
Switching Frequency Characteristics ..............................................................................................................24
4.4
Over Current Threshold Characteristics..........................................................................................................25
5
Design and Applications Information ........................................................................................ 27
5.1
Input Voltage Resistor Divider on VIN Pin.......................................................................................................28
5.2
Isolated Voltage Loop and Output Voltage Feedback on FB Pin ....................................................................30
5.2.1
Resistor Divider Design for Output Voltage ......................................................................................31
5.2.2
Compensation Network Design ........................................................................................................31
5.2.3
RS2 and Rf1 Design .........................................................................................................................33
5.3
Current Sensing and Over Current Protection ................................................................................................34
5.3.1
Current Sensing Through ISNS Pin ..................................................................................................34
5.3.2
Average Current Signal and Over Power Limitation .........................................................................35
5.3.3
Cycle by Cycle Current Protection through OCP Pin........................................................................36
5.3.4
Peak Current and Average Current Relationship .............................................................................38
5.4
SW Pin to MOSFET Gate ...............................................................................................................................39
5.5
VDD, Signal Ground (SGND) and Power Ground (PGND) .............................................................................39
5.6
90W/20V Signal Stage PFC Adaptor Schematic and Bill of Materials (BOM).................................................41
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 5
88EM8040/88EM8041
Datasheet
6
Mechanical Drawings .................................................................................................................. 43
6.1
Mechanical Drawings ......................................................................................................................................43
7
Part Order Numbering/Package Marking .................................................................................. 45
7.1
Part Order Numbering ..................................................................................................................................45
7.2
Package Markings...........................................................................................................................................46
A
Revision History .......................................................................................................................... 47
Doc. No. MV-S104983-01 Rev. A
Page 6
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
List of Figures
List of Figures
Figure 1:
1
PFC Flyback Circuit Diagram ............................................................................................................3
Signal Description ........................................................................................................................... 11
Figure 2:
SOIC-8 Pin Diagram (Top View).......................................................................................................11
2
Electrical Specifications ................................................................................................................. 13
3
Functional Description.................................................................................................................... 19
Figure 3:
4
5
Top Level Block Diagram..................................................................................................................19
Functional Characteristics.............................................................................................................. 21
Figure 4:
IDD Quiescent (IDD_QST) vs. VDD ...................................................................................................21
Figure 5a:
IDD vs. VDD (VDD_ON) ........................................................................................................................21
Figure 5b:
IDD vs. VDD (VDD_ON)........................................................................................................................21
Figure 6a:
IDD Operation (IDD_OP) vs. Temperature ........................................................................................22
Figure 6b:
IDD Operation (IDD_OP) vs. Temperature ........................................................................................22
Figure 7:
VDD On/Off vs. Temperature ...........................................................................................................22
Figure 8:
IDD vs. VFB (OVP) .............................................................................................................................23
Figure 9:
VFB_OVP vs. Temperature ..............................................................................................................23
Figure 10:
VFB_OVP Hysteresis vs. Temperature ............................................................................................23
Figure 11:
VFB_OVP_LATCH vs. Temperature ................................................................................................23
Figure 12:
Normal Regulation Reference (VFB_REG) vs. Temperature ...........................................................24
Figure 13:
Switching Frequency vs. Temperature .............................................................................................24
Figure 14:
Over Current (VIOVER) vs. Input Voltage VIN Peak Value).............................................................25
Figure 15:
Over Current (VIOVER) vs. Temperature .........................................................................................25
Figure 16:
VIOVER_CYC_ON/OFF vs. Temperature ........................................................................................26
Design and Applications Information ............................................................................................ 27
Figure 17:
Internal Block for Zero-cross Detection, Brown-out Protection .........................................................28
Figure 18:
Peak Detecting Signal for Predictive Sinusoidal AC Voltage............................................................29
Figure 19:
Input Voltage Resistor Divider Layout Guidelines ............................................................................30
Figure 20:
Secondary Compensation Network with Opt-coupler .......................................................................30
Figure 21:
Bode Plot of Compensation Network at Secondary Side .................................................................32
Figure 22:
Bias Current for Offset Voltage on FB Pin ........................................................................................33
Figure 23:
Current Sensing Circuit.....................................................................................................................34
Figure 24:
Current Sensing and Cycle by Cycle Over Current Protection Circuit ..............................................36
Figure 25:
Current Sensing and Cycle by Cycle Over Current Protection Waveforms ......................................36
Figure 26:
SW Pin Layout Guidelines ................................................................................................................39
Figure 27:
VDD Decoupling Capacitor and Ground Layout Guidelines .............................................................40
Figure 28:
90W/20V Single Stage PFC Adaptor Schematic ..............................................................................41
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 7
88EM8040/88EM8041
Datasheet
6
Mechanical Drawings ...................................................................................................................... 43
Figure 29:
7
A
8-Lead SOIC Mechanical Drawing ...................................................................................................43
Part Order Numbering/Package Marking....................................................................................... 45
Figure 30:
88EM8040/88EM8041 Sample Ordering Part Number ....................................................................45
Figure 31:
88EM8040/88EM8041 Package Marking .........................................................................................46
Revision History ............................................................................................................................... 47
Doc. No. MV-S104983-01 Rev. A
Page 8
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
List of Tables
List of Tables
1
2
Signal Description ............................................................................................................................ 11
Table 1:
Pin Descriptions ................................................................................................................................11
Table 2:
Pin Descriptions ................................................................................................................................12
Electrical Specifications .................................................................................................................. 13
Table 3:
Absolute Maximum Ratings ..............................................................................................................13
Table 4:
Recommended Operating Conditions...............................................................................................14
Table 5:
Electrical Characteristics ..................................................................................................................15
3
Functional Description..................................................................................................................... 19
4
Functional Characteristics............................................................................................................... 21
5
Design and Applications Information ............................................................................................. 27
Table 6:
Comparison Between Average Current Mode and Critical Transition Mode Control........................27
Table 7:
Current Sensing Circuit.....................................................................................................................35
Table 8:
Current Sensing Resistor Selection Reference ................................................................................35
6
Mechanical Drawings ....................................................................................................................... 43
7
Part Order Numbering/Package Marking........................................................................................ 45
Table 9:
A
88EM8040/88EM8041 Part Order Options .......................................................................................45
Revision History ............................................................................................................................... 47
Table 10:
Revision History ................................................................................................................................47
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 9
88EM8040/88EM8041
Datasheet
THIS PAGE INTENTIONALLY LEFT BLANK
Doc. No. MV-S104983-01 Rev. A
Page 10
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Signal Description
Pin Configurations
1
Signal Description
1.1
Pin Configurations
Figure 2: SOIC-8 Pin Diagram (Top View)
1.2
PGND
1
8
SW
SGND
2
7
VDD
ISNS
3
6
OCP
VIN
4
5
FB
Pin Descriptions
Table 1:
Pin Descriptions
Pi n #
P in N a m e
P i n Ty p e
P in D e s c r i p t io n
1
PGND
Ground
Power Ground
2
SGND
Ground
Signal Ground
3
ISNS
Input
Current Sense
4
VIN
Input
Voltage Input
5
FB
Input
Feedback
6
OCP
Input
Over Voltage Current Protection
7
VDD
Supply
IC Supply Voltage
8
SW
Output
Switch
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 11
88EM8040/88EM8041
Datasheet
Table 2:
Pin Descriptions
P in #
P in N a m e
Pi n F u nc t io n
1
PGND
Power Ground
Connected to the source of the primary MOSFET. The PCB trace from the power ground to the
source of the primary MOSFET must be kept as short as possible.
To avoid any switching noise interruption on signal processing, PGND and SGND remain
seperate inside the IC.
2
SGND
Signal Ground
Must be connected to the power ground with the Kelvin sensing connection, so that SGND has
dedicated trace and connections and provides noiseless environment for the signal processing.
3
ISNS
Current Sense
Sense resistor varies from 0.15Ω at 120W rated load to 0.44Ω for 40W rated load. Used for
current shaping and for over current protection.
4
VIN
Voltage Input
• Connects to resistive divider at input AC line “phase” to GND. Voltage applied is a half
rectified sine wave scaled down by the input resistive divider.
• Voltage input pin is a high impedance input pin. An impedance of 2M (typical) is
recommended to be designed from the input AC “phase” to GND in order to reduce the
standby power. Higher impedance is preferred with the right PCB design on this pin signal.
• Voltage is compared with a threshold reference (VVIN_BR) to detect the zero-cross location
of the input sine wave and synthesize (regenerate) the input sine wave. This sine wave is
used to generate the current reference.
• Brown-out protection1 function is also provided by this pin. A resistor devider with a 100:1
ratio from the highside resistor to the lowside resistor is corresponding to the “brown-out
protection” input voltage as 50V (RMS). Increasing that raio will increase the “brown-out
voltage”. Please refer to footnote1 for further explaination.
5
FB
Feedback
It is connected to the emitter of the transistor on the secondary side of the opto coupler
(referred to within the Appication Information section). The output voltage is scaled to 2.5V with
100% rated value. Transition from soft start to normal regulation at 87.5% rated VFB. Over
voltage shutdown SW gate signal at 107% rated VFB and recover once below VFB_OVP.
There is another threshold (VFB_OVP_LATCH) as 3.77V on the FB pin. When FB Voltage reaches
VFB_OVP_LATCH, SW signal is shutdown and latched until another VDD power on reset.
6
OCP
Over Current Protection
Used to turn off the MOSFET when it is pulled as logic low
7
VDD
IC Supply Voltage
Nominal voltage is typical 12V and the Under Voltage Lock Out (UVLO) for VDD <VDD_UVLO
(Table 5). Start voltage of IC is VDD_On (Table 5) and maximum voltage is 16V (Table 5). It
should be clamped by a zener for protection in the system design.
8
SW
Switch
PWM gate signal for the switch. Connects to the gate of external MOSFET. It is the DSP core
output for ON/OFF time buffered through the internal adaptive driver.
1. Brown-out voltage is determined by Ra, Rb and Rc as shown in Figure 1. Please refer to page 29 for a further
understanding.
Doc. No. MV-S104983-01 Rev. A
Page 12
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Electrical Specifications
Absolute Maximum Ratings
2
Electrical Specifications
2.1
Absolute Maximum Ratings
Table 3:
Absolute Maximum Ratings1
NOTE: Stresses above those listed in Absolute Maximum Ratings may cause permanent device failure. Functionality at or
above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device
reliability.
Sy m b o l
P a r a m e t er
Min
Max
U n i ts
VDD
Power Supply (Voltage to PGND=SGND)
-0.3
18
V
VIsns
Voltage at ISNS pin
-0.5
3
V
VOCP
Voltage at OCP pin
-0.3
5.5
V
VVIN
Voltage at VIN pin
-0.3
5.5
V
VFB
Voltage at FB pin
-0.3
5.5
V
ISW
Driver Current (Instantaneous Peak)
2
A
θJA
Thermal Resistance SOIC-8
156.5
°C/W
Thermal Resistance DIP-8
89.5
°C/W
85
°C
125
°C
150
°C
2
kV
TA
Operating Ambient Temperature Range2
TJ
Maximum Junction Temperature
TSTOR
Storage Temperature Range
VESD
ESD Rating3
-40
-65
1. Exceeding the absolute maximum rating may damage the device.
2. Specifications over the -40°C to 85°C operating temperature ranges are assured by design, characterization and
correlation with statistical process controls.
3. Devices are ESD sensitive. Handling precautions recommended. Human Body model, 1.5kΩ in series with 100pF.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 13
88EM8040/88EM8041
Datasheet
2.2
Table 4:
Recommended Operating Conditions
Recommended Operating Conditions1
Sy m b o l
P a r a m e te r
M in
TA
Operating Ambient Temperature2
TJ
Junction Temperature
Ty p
Max
U ni ts
-40
85
°C
-20
125
°C
1. This device is not guaranteed to function outside the specified operating temperature range.
2. Over the –40°C to 80°C operating temperature ranges are assured by design, characterization, and correlation with
statistical process controls.
Doc. No. MV-S104983-01 Rev. A
Page 14
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Electrical Specifications
Electrical Characteristics
2.3
Table 5:
Electrical Characteristics
Electrical Characteristics
NOTE: A 12V supply voltage is applied and the ambient temperature (TA) = 25°C.
Sy m b o l
Parameter
C on d it io n s
M in
Ty p
Max
Units
7.0
12
16
V
VDD Supply
VDD
Supply Voltage
VDD_ON
VDD Power On Threshold
VDD_UVLO
VDD Power Off Threshold
(UVLO)
VDD_UVLO_HYS
VDD_UVLO Hysteresis
IDD_QST
VDD Quiescent Current1
VDD = 12V
IDD_OP
VDD Operating Current
VDD = 12V;
CGate = 1nF
FSW = 118kHz
VIN=0
After VDD is powered
up and running
11.9
V
7.0
V
4.8
5
V
95
µA
5.2
mA
Thermal Shutdown
TSD
Thermal Shutdown
150
°C
TSD_HYS
Hysteresis for Thermal
Shutdown
25
°C
10.0
V
Adaptive Output Gate Driver
VG_HI
Minimum Gate High Voltage2
VDD = 12V
CGate = 1nF
Sourcing 500mA
VG_LO
Maximum Gate Low Voltage3
VDD = 12V
CGate = 1nF
Sinking 500mA
RDSON
Gate Drive Resistance
Sourcing 75mA
T=25 C
2.4
Ω
Gate Drive Resistance
Sinking 20mA
T=25 C
2.0
Ω
ISW_PK
Driver Peak Current
CGate = 10 nF
VDD = 12 V
tR
Rise Time
CGate = 1 nF
35
ns
CGate = 10 nF
125
ns
CGate = 1 nF
35
ns
CGate = 10 nF
145
ns
tF
DMAX
Fall Time
Maximum Duty Cycle
2.0
V
A
97
Copyright © 2009 Marvell
October 5, 2009, Preliminary
2.0
%
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 15
88EM8040/88EM8041
Datasheet
Table 5:
Electrical Characteristics (Continued)
NOTE: A 12V supply voltage is applied and the ambient temperature (TA) = 25°C.
Sy m b o l
Parameter
DMIN
Minimum Duty Cycle
C on d it io n s
M in
Ty p
Max
3.0
Units
%
Feedback/Overvoltage
VFB_REG
Normal Regulation Reference
IC powered on
2.55
V
VFB_OVP
Over Voltage Protection
Threshold
At 107% of VFB_REG.
2.71
V
VFB_OVP_HYS
Over Voltage Protection
Hysteresis
VFB_OVP_LATCH
Over Voltage Protection Latch
0.108
V
3.77
V
Current Sensing and Current Protection4
VIOVER_TH1
Over Current Threshold Zone
15
Peak value of half-sine
voltage at VIN:
1.26<VIN<1.89Vpk6
397
mV
VIOVER_TH2
Over Current Threshold Zone
25
Peak value of half-sine
voltage at VIN:
1.89<VIN<2.59Vpk7
329
mV
VIOVER_TH3
Over Current Threshold Zone
35
Peak value of half-sine
voltage at VIN:
2.59< VIN<3.43Vpk8
269
mV
VIOVER_TH4
Over Current Threshold Zone
45
Peak value of half-sine
voltage at VIN:
3.43<VIN<3.85Vpk9
202
mV
VIOVER_CYC_ON
Cycle by cycle current
protection logic input (OCP
pin) threshold for SW on10
1.68
V
VIOVER_CYC_OFF
Cycle by cycle current
protection logic input (OCP
pin) threshold for SW off11
1
V
88EM8040 Switching Frequency Oscillator
FSW
Frequency
(Average Mode)
kHz
88EM8041 Switching Frequency Oscillator
FSW
Frequency
118
kHz
1. Quiescent Current: VDD power supply current before VDD first time reaches VDD_On.
2. Considering the voltage drop on the internal driver MOSFET during current sourcing.
3. Considering the voltage drop on the internal driver MOSFET during current sinking.
Doc. No. MV-S104983-01 Rev. A
Page 16
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Electrical Specifications
Electrical Characteristics
4. To achieve almost constant power limit for the universal input range, current protection self-adjusts thresholds in four
zones of input voltage levels. A margin of 50% compared to the rated current is considered for the threshold current
values.
5. Threshold of negative voltage drop across Rsns due to instantaneous current
6. With input divider ratio of 1/100, these values are equivalent to 90 Vrms<Vline<135 Vrms.
7. With input divider ratio of 1/100, these values are equivalent to 135 Vrms<Vline<185 Vrms.
8. With input divider ratio of 1/100, these values are equivalent to 185 Vrms<Vline<245 Vrms.
9. With input divider ratio of 1/100, these values are equivalent to 245 Vrms<Vline<275 Vrms.
10.When OCP pin is above VIOVER_CYC_ON as 1.68V, then SW is controlled by the PWM block for on and off.
11.When OCP pin is below VIOVER_CYC_OFF as 1V, then SW is turned off and released at the next switching cycle if OCP
pin is above VIOVER_CYC_ON
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 17
88EM8040/88EM8041
Datasheet
THIS PAGE INTENTIONALLY LEFT BLANK
Doc. No. MV-S104983-01 Rev. A
Page 18
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Functional Description
Overview
3
Functional Description
3.1
Overview
The 88EM8040/88EM8041 is a high performance, low-cost with minimum component count Power
Factor Correction (PFC) Controller. The device is used for controlling Universal input flyback
converters in systems or standalone products. The high performance of 88EM8040/88EM8041 is
accompanied with its small size and simplicity of application. Figure 3 shows the top level block
diagram.
Figure 3: Top Level Block Diagram
88EM8040/8041
Over
Temperature
Clock
Oscillator
Current
Protection
Protection
Management
I_over
Fault
Driver Disable
Current
Amplifier
ISNS
T_over
Vo_over
I_over
MUX
Switcher
&
ADC
FB
Output
Voltage Level
Detect
Gate
Driver
DSP
Core
State Machine
SW
Vo_over
Zero Cross
Detect
VIN
Current
Protection
Threshold
Selection
PGND
SGND
„
Note
Power
Distribution
and
Bandgaps
Serial Data
Interface
VDD
OCP
I_over, Vo_over, and T_over are the over current, over voltage, and over temperature
signals respectively.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Startup Setting
or
Frequency
Setting
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 19
88EM8040/88EM8041
Datasheet
3.2
Signal Process and Functions
The 88EM8040/88EM8041 boost power board includes three inputs:
„
„
„
Resistive divider signal from AC line voltage
Feedback from the output DC bus
Voltage across the current sense resistor
The input phase voltage to ground (half rectified sine wave) scaled down by the input resistive
divider is applied to pin VIN. This signal used for estimation of the AC line voltage and regeneration
of the AC sine wave. It is also used for voltage level detection that produces adaptive multiple
thresholds for the over current limit and guarantees a constant power limit from the AC source.
Signal from the DC bus voltage through the muxed 12-bit Analog-to-Digital Converter (ADC)
provides the feedback data for the voltage PI control loop.
HF switching current pulse signal is retrieved from the voltage drop across the current sense resistor
that is negative to GND. This signal after HF noise filter and fixed gain amplification, is transferred
through the muxed 12-bit ADC to the digital current loop and the current error amplifier. The
reference current for the current control PI loop is provided by multiplying the voltage error amplifier
output and the regenerated sinusoidal line voltage information.
Doc. No. MV-S104983-01 Rev. A
Page 20
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Functional Characteristics
VDD Characteristics
4
Functional Characteristics
The following applies unless otherwise noted: VIN = 60Hz half-wave sinusoidal from 0V to the peak
voltage (VPK) given in the test conditions of each graph. TA = 25°C.
All measurement readings are typical.
4.1
VDD Characteristics
Figure 4: IDD Quiescent (IDD_QST) vs. VDD
100
90
80
IDD (μA)
70
60
50
40
30
20
10
0
0
2
4
6
8
10
12
VDD (V)
Test Conditions:
„
„
„
„
VIN = 0V
FSW = 118kHz
„
VFB = 0V
CGate = 1nF
V_Isns = 0V
Figure 5a: IDD vs. VDD (VDD_ON)
Figure 5b: IDD vs. VDD (VDD_ON)
7
6
VDD Falling
VDD Rising
5
VDD Falling
6
VDD Rising
5
IDD (mA)
IDD (mA)
4
3
4
3
2
2
1
1
0
0
0
2
4
6
8
10
12
14
16
0
2
4
6
VDD (V)
Test Conditions:
„
„
VIN = 0V
FSW = 118kHz
„
„
„
VFB = 0V
CGate = 1nF
V_Isns = 0V
Test Conditions:
„
„
VIN = 0V
FSW = 118kHz
Copyright © 2009 Marvell
October 5, 2009, Preliminary
8
10
12
14
16
VDD (V)
„
„
„
VFB = 2.4V
CGate = 1nF
V_Isns = 0V
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 21
88EM8040/88EM8041
Datasheet
Figure 6b: IDD Operation (IDD_OP) vs.
Temperature
7
7
6
6
5
5
IDD (mA)
IDD (mA)
Figure 6a: IDD Operation (IDD_OP) vs.
Temperature
4
3
4
3
2
2
1
1
0
0
-40
-20
0
20
40
60
80
-40
-20
0
Test Conditions:
„
„
VFB = 0V
CGate = 1nF
V_Isns = 0V
„
„
VDD = 12V
VIN = 0V
FSW = 118kHz
„
20
40
60
80
Temperature (°C)
Temperature (°C)
„
Test Conditions:
„
„
„
VDD = 12V
VIN = 0V
FSW = 118kHz
„
„
„
VFB = 2.4V
CGate = 1nF
V_Isns = 0V
Figure 7: VDD On/Off vs. Temperature
14
12
ON
VDD (V)
10
8
OFF
6
4
Hysteresis
2
0
-40
-20
0
20
40
60
80
Temperature (°C)
Test Conditions:
„
„
VIN = 0V
FSW = 118kHz
„
„
„
FFB = 2.4V
CGate = 1nF
V_Isns = 0V
Doc. No. MV-S104983-01 Rev. A
Page 22
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Functional Characteristics
VFB Characteristics for Over Voltage Protection
4.2
VFB Characteristics for Over Voltage Protection
Figure 8: IDD vs. VFB (OVP)
Figure 9: VFB_OVP vs. Temperature
3.0
5.5
OVP Threshold
2.5
5.0
Recovery Threshold
4.5
V F B (V )
IDD (mA)
2.0
4.0
1.5
1.0
VFB Falling
3.5
0.5
VFB Rising
0.0
3.0
2.0
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
-40
3.0
-20
0
Test Conditions:
„
VDD = 12V
„
„
„
VIN = 0V
Test Conditions:
FSW = 118kHz
CGate = 1nF
V_Isns = 0V
„
20
40
60
80
Temperature ( C)
VFB (V)
„
„
Figure 10: VFB_OVP Hysteresis vs. Temperature
„
„
VDD = 12V
VIN = 0V
„
FSW = 118kHz
CGate = 1nF
V_Isns = 0V
Figure 11: VFB_OVP_LATCH vs. Temperature
4.0
0.30
3.5
0.25
3.0
2.5
VFB (V)
VFB (V)
0.20
0.15
2.0
1.5
0.10
1.0
0.05
0.5
0.00
0.0
-40
-20
0
20
40
60
80
-40
-20
0
Test Conditions:
„
VDD = 12V
„
„
„
VIN = 0V
„
FSW = 118kHz
CGate = 1nF
V_Isns = 0V
Test Conditions:
„
„
VDD = 12V
VIN = 0V
Copyright © 2009 Marvell
October 5, 2009, Preliminary
20
40
60
80
Temperature (°C)
Temperature ( C)
„
„
„
FSW = 118kHz
CGate = 1nF
V_Isns = 0V
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 23
88EM8040/88EM8041
Datasheet
Figure 12: Normal Regulation Reference
(VFB_REG) vs. Temperature
3.0
2.9
2.8
VFB (V)
2.7
2.6
2.5
2.4
2.3
2.2
2.1
2.0
-40
-20
0
20
40
60
80
Temperature (°C)
Test Conditions:
„
„
VDD = 12V
VIN = 2V
„
„
4.3
„
FSW = 118kHz
CGate = 1nF
V_Isns = 0V
Switching Frequency Characteristics
Figure 13: Switching Frequency vs. Temperature
140
FSW (8041)
Frequency (kHz)
120
100
80
FSW (8040)
60
40
20
0
-40
-20
0
20
40
60
80
Temperature (°C)
Test Conditions:
„
„
VDD = 12V
VIN = 0V
„
VFB = 2.4V
„
CGate = 1nF
V_Isns = 0V
„
Doc. No. MV-S104983-01 Rev. A
Page 24
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Functional Characteristics
Over Current Threshold Characteristics
4.4
Over Current Threshold Characteristics
Figure 14: Over Current (VIOVER) vs. Input Voltage
VIN Peak Value)
0.45
0.40
0.35
V CS (V )
0.30
0.25
0.20
0.15
0.10
0.05
0.00
0
1
1
2
2
3
3
4
4
5
5
VIN (V)
Test Conditions:
VDD = 12V
FSW = 118kHz
„
„
„
VFB = 2.4V
„
CGate = 1nF
V_Isns = 0V
„
Figure 15: Over Current (VIOVER) vs. Temperature
450
VIN = 1.5V
400
VIN = 2.25V
350
VCS (V)
300
VIN = 3V
250
VIN = 3.7V
200
150
100
50
0
-40
-20
0
20
40
60
80
Temperature ( C)
Test Conditions:
„
„
VDD = 12V
FSW = 118kHz
„
VFB = 2.4V
„
CGate = 1nF
V_Isns = 0V
„
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 25
88EM8040/88EM8041
Datasheet
Figure 16: VIOVER_CYC_ON/OFF vs. Temperature
2
VIOVER_CYC_ON
1.8
1.6
Viover (V)
1.4
1.2
VIOVER_CYC_OFF
1
0.8
0.6
0.4
0.2
0
-40
-20
0
20
40
60
80
Temperature (°C)
Test Conditions:
„
„
VDD = 12V
VIN = 0V
„
VFB = 2.4V
„
CGate = 1nF
V_Isns = 0V
„
Doc. No. MV-S104983-01 Rev. A
Page 26
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
5
Design and Applications Information
The flyback (isolated buck/boost) topology is used to simplify the two stage front-end design to a
single isolated Power Factor Correction (PFC) conversion stage. Compared to the two stage PFC
structure, a single stage PFC is a more cost effective solution.
The 88EM8040/88EM8041 chip control algorithm uses Average Current Mode Control for power
factor correction applications with low harmonic distortion and good noise immunity. The IC senses
the output voltage and forces it to follow the reference voltage to produce a stable DC output voltage
matching the design requirements. It also senses the primary current and forces the average signal
of the primary current to follow the sinusoidal current reference, therefore achieving power factor
correction. Compared to other competitors parts operating under Critical Transition Mode Control,
the 88EM8040/88EM8041 has many advantages as shown in Table 6l
Table 6:
Comparison Between Average Current Mode and Critical Transition
Mode Control
C r iti c a l Tr a n s m it io n M o d e C on t r o l
Av e r a g e C u r r e n t M o d e C o n t r o l
High peak current on switch
Low peak current on switch
High diode peak current at secondary side
Low diode peak current at secondary side
Variable switching frequency with lowest
switching frequency at peak input voltage
Fixed switching frequency
Big transformer
Small transformer
Low efficiency
High efficiency
Low power factor / higher THD at high line low
load
High power factor / lowerer THD at high line low
load due to adaptive loop control
Difficult to achieve high power
Easy to achieve high power
High cost
Low cost
Marvell's innovative PFC control technology improves the performance of the isolated flyback
converter used in PFC applications. The flyback PFC solution based on the 88EM8040/88EM8041
provides customers with a simple structure, low cost without sacraficing performance compared with
the other industry solutions currently on the market.
The following sections provides guidelines for the application design, component selection, and
board layout all in order to improve flyback single stage PFC performance. There are three analog
input signals and one logic input signal listed below are required from the power train to the
controller IC 88EM8040/88EM8041.
1.
2.
3.
4.
Input voltage signal at VIN pin is a half sinusoidal waveform. It is fed into the VIN pin through
the input voltage resistor divider. This is for the line frequency zero-cross detection for PFC.
Output voltage signal at FB pin is the output voltage through the resistor divider plus the
compensation and opto-coupler to feedback on FB pin. This is for the voltage loop regulation.
Current sensing signal through the sensing resistor to the ISNS pin. This is for the average
current mode control to achieve a good sinusoidal current waveform and high power factor.
The input over current protection (OCP) signal is a logic signal instead of an analog signal. It is
used to shut down the output at the SW pin when it is pulled low.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 27
88EM8040/88EM8041
Datasheet
The output signal from the 88EM8040/88EM8041 is the PWM gate drive signal from the SW pin.
The switching frequency on the 88EM8040 device is fixed to 60kHz while the 88EM8041 is fixed to
120kHz. Both device tolerances are shown in the electrical characteristics table.
5.1
Input Voltage Resistor Divider on VIN Pin
An accurate peak detection signal and zero-cross detection for regenerating the input sinusoidal
voltage is the most important issue for a proper current shaping and total harmonic distortion (THD)
improvement. If the threshold reference is too high, near the peak area, the calculation may lose
accuracy because of the low slope. On the other hand, if the threshold reference is too low, there
could be an error on zero-cross detection due to the possible distortions near the zero-crossing. For
a universal input voltage range (85Vac~270Vac) the optimum accuracy would be achieved if the
threshold level is around 30 degree of the line cycle.
Figure 17: Internal Block for Zero-cross Detection, Brown-out Protection
VDCin
88EM8040
/8041
Brown-Out
Protection
Vline _ pk
AC
IN
Predictive
Sinusoidal
AC Voltage
Phase (φ )
Ra
Rb
VIN
Rc
Peak
detecting
pulse
Zero
Crossing
Power Limit
Threshold
Selection
To get a proper sinusoidal AC voltage, UVLO, and peak voltage detection, we need to choose the
right value for the sensing resistors: Ra, Rb, and Rc, as shown in Figure 17. If the value is too small
there will be higher power loss and if the value is too big the resistor will not properly work due to the
picking noise of the VIN signal. The recommended values are shown below:
Ra + Rb
------------------ = 100
--------- = 1.8MΩ
----------------Rc
1
18kΩ
Equation (1)
For the input voltage resistor divider, the appropriate combination based on the voltage / power
rating of the resistors should also be considered.
Doc. No. MV-S104983-01 Rev. A
Page 28
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
Input Voltage Resistor Divider on VIN Pin
Figure 18: Peak Detecting Signal for Predictive Sinusoidal AC Voltage
Vline_pk
Vline_pk
VVIN_BR = 0.72V (Typ.)
V ( φ ) = Vline_pk × sin φ
Half line cycle
Half line cycle
φ
φ
N
φ
M
φ
N
Peak detecting Pulse
As can be seen in Figure 17, the internal peak detecting circuit generates peak detecting pulse
through the inside comparator which has a threshold voltage of 0.72V (typical). Processing of this
pulse in DSP core calculates the mid-point (peak point) and the zero-crossing point of the sinusoidal
waveform. The phase angle of φ is calculated using the width of the high and low signal M&N.
N = (π – 2φ)
Equation (2)
M = (π + 2φ )
Equation (3)
φ = (M – N) ⁄ 4
Equation (4)
Peak value of the sinusoidal waveform is introduced by the relation:
V line_pk = V ( φ ) ⁄ sin ( φ )
Equation (5)
The signal that appears on the VIN pin is a half sinusoidal voltage waveform and its peak line value
has to be higher than VVIN_BR of 0.72V (typical) for normal operation. Whenever the VVIN_BR is less
than 0.72V at the peak line value, it is considered as a Brown-out condition. The IC only generates
6% duty during the brown-out condition. To adjust the brown-out protection point, the resistance
value of Ra, Rb and Rc can be changed. With the recommended resistor values in Equation (1) the
brown-out protection voltage is 72V peak value, which is around a 50V RMS value for the input line
voltage.
The layout of Ra, Rb and Rc should be kept as close as possible to the VIN pin, as shown in
Figure 19 in order to have a proper layout on the input voltage resistor divider and to avoid noise
picking. It is also recommended that a 0.1nF–10nF capacitor is connected between the VIN pin and
ground with the layout also close to this pin.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 29
88EM8040/88EM8041
Datasheet
Figure 19: Input Voltage Resistor Divider Layout Guidelines
Ra
OCP
ISNS
Cc
PGND
88EM8040/
8041
Rb
Rc
SW
SGND
VIN
VDD
FB
Keep layout of Rb, Rc and Cc as
close as possible to Vin pin to
keep high noise immunization
5.2
Isolated Voltage Loop and Output Voltage Feedback
on FB Pin
The88EM8040/88EM8041 IC integrates the voltage loop into digital DSP core. This internal voltage
loop has the lower corner frequency for the PFC requirement. The FB pin is the internal voltage loop
feedback signal input. The voltage reference of the IC is 2.5V for the rated output voltage.
The Flyback PFC is an isolated power system, which needs the opto-coupler device transferring the
output voltage amplitude signal to the FB pin. Since the CTR (Current Transfer Ratio) parameter of
this opto-coupler has a big tolerance and shifts with the temperature, an additional voltage reference
and compensation is required at the secondary side. This secondary voltage loop circuit can use a
low voltage adjustable shunt regulator such as the TLV431 or a dual op-amp with a reference
voltage such as the TSM1014 to constitute the error amplifier with compensation network. Figure 20
shows the typical voltage feedback loop circuit.
Figure 20: Secondary Compensation Network with Opt-coupler
VOut
RS4
VFB
VDD
CS2
CS1
R S2
R S5
1
2
Verr
Vref
R f1
Doc. No. MV-S104983-01 Rev. A
Page 30
RS3
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
Isolated Voltage Loop and Output Voltage Feedback on FB Pin
It is well known that a single stage PFC with flyback topology is not easy to maintain enough stability
while at the same time keeping a good sinusoidal current waveform and power factor under a wide
input voltage and load condition. In order to achieve enough stability as the first criteria, the
compensation network at the secondary should be designed properly, which will be described in the
following paragraph. In order to achieve a good sinusoidal current waveform and power factor, the
voltage loop regulation coefficient should also be designed properly corresponding to the different
input voltages. The adaptive voltage loop coefficient is designed inside the IC to select different
voltage regulation parameters. This achieves a much better power factor and sinusoidal current
waveform compared to any of the single stage PFC power system on the market now. This is why
there is also another voltage loop regulation designed inside of the IC while an external voltage loop
compensation is designed at the secondary side of the flyback system.
5.2.1
Resistor Divider Design for Output Voltage
The design of RS3 and RS4 is based on the rated output voltage and the power loss of the resistor
divider. In order to keep low power consumption on the resistor divider and good signal to noise
immunity, a minimal total resistance of 20kΩ (Typical) is recommended for the pair of resistors RS3
and RS4.
The relation among the output voltage, reference voltage and resistor divider is as;
R S3
V out × ----------------------- = V ref
R S3 + R S4
Equation (6)
If the output voltage is designed as 20V, reference voltage is 2.5V and RS4 is selected as 15.4kΩ,
the value RS3 is calculated from equation (6) as 2.21 kΩ.
5.2.2
Compensation Network Design1
The compensation network should be designed by selecting the value of RS5, CS1 and CS2. A typical
compensation network is constructed in Figure 20. The transfer function is derived as;
1 + sR S5 C S1
V err ( s )
1
H ( s ) = -------------------- = -------------------------------------- × ----------------------------------------------------V OUT ( s )
R S4 ( C S1 + C S2 )
C s1 C s2
s ⎛⎝ 1 + s ------------------------ R S5⎞⎠
C S1 + C S2
Equation (7)
Equation (7) is simplifed as;
( s + ωz )
H ( s ) = K × ---------------------s ( s + ωp )
Equation (8)
Where:
1
1
1
K = ------------------ ; ω z = ------------------ ; ω p = --------------------------------R S5 C S1
C S1 C S2
R S4 C S2
------------------------ R S5
C S1 + C S2
Equation (9)
The criteria to design the network in Figure 20 is to provide enough DC gain and attenuate the
double line frequency ripple by properly selecting the right zero and pole parameters. In order to
meet these criteria, zero ωz should be placed below the double line frequency (100/120Hz) and pole
1. Please refer to the 88EM8041 90W application note for a detailed derivation of open-loop transfer function for the overall flyback circuit.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 31
88EM8040/88EM8041
Datasheet
ωp should be placed above the double line frequency. The magnitude of the gain around the double
line frequency should below the unity gain, which is 0db axis in the bode plot, in order to attenuate
the double line frequency ripple.
The following is a design example of this network: RS4=15.4kΩ, RS5=2kΩ, CS1=4.7μF and
CS2=47nF. This produces a zero and pole as: ωz = 16.94Hz, ωp = 1.71kHz. The bode plot is shown in
Figure 21. The magnitude of the gain at 100Hz to 120Hz is about -18dB, therefore the double line
frequency ripple is attenuated. The parameters are designed to maintain the stability for the single
stage PFC system.
Figure 21: Bode Plot of Compensation Network at Secondary Side
magnitude (db)
100
50
0
-50
-4
10
-2
10
0
10
2
10
4
10
6
10
Frequency (Hz)
0
Phase (degree)
-20
-40
-60
-80
-100
-4
10
-2
10
0
10
2
10
4
10
6
10
Frequency (Hz)
In order to decrease the time for the transconductance error amplifier at the secondary to quit the
saturation process and reduce the output voltage overshoot at startup, a Zener diode is required.
The zener diode is connected between the error amplifier output terminal to ground. This reduces
the overshoot and improves the startup performance, because the zener provides a bias current
before the transconductance error amplifier sinks current. Because of the tolerance of the
opto-coupler CTR, the output voltage of the error amplifier under a steady state should not become
too low so as to keep the sufficient output regulation capability.
In the 20V/90W reference design, a 6.8V Zener is selected and output of the error amplifier is set as
about 5 to 6 volts under steady state. The output voltage of the transconductance error amplifier is
around one third of the rated output voltage under steady state.
Doc. No. MV-S104983-01 Rev. A
Page 32
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
Isolated Voltage Loop and Output Voltage Feedback on FB Pin
5.2.3
RS2 and Rf1 Design
The RS2 and Rf1 design is mainly based on the opto-couplers current transfer ratio(CTR) Which
should be around 100% to 200%. RS2 is designed to produce around 1mA current at the LED side
of the opto-coupler. Rf1 is designed to produce 2.5V feedback voltage to close the loop under a
stead state. If Rf1 is designed at 1.24kΩ, the current at transistor side of the opto-coupler should be
designed at 2mA (typical). This should have enough signal to noise ratio in the practical design. The
feedback resistor (Rf1) should be kept close to the opto-coupler to avoid noise in the layout.
The output of PFC Flyback has double line frequency ripple voltage. At the steady state operation
condition, the FB pin voltage transferred from secondary side also has this double line frequency
ripple voltage. The ripple voltage amplitude on the FB pin is determined by the output voltage ripple
amplitude and the gain from the output voltage to the FB pin (referred in the previous section
Section 5.2.2, Compensation Network Design, on page 31). It is noticed that there is an attenuated
ripple appearing at the output of the amplifier with the minus phase shift from the output voltage
ripple. Therefore, the ratio of ripple voltage amplitude over the DC voltage value of FB pin is bigger
than the ratio of output ripple over DC output voltage. If the output ripple voltage is too big in certain
applications, the FB pin voltage peak value might trigger the internal FB OVP threshold, which is
about 7% on the top of the reference value. This will heavily distort the input current waveform and
disturb the stability of the system. In order to solve this issue, it is recommended to use a constant
offset voltage circuit, as show in Figure 22. This circuit consists of a diode (ZD1), and two resistors
(Rf2 and Rf3). This will provide a bias current from the bias winding so as to produce a bias voltage
on the FB pin. Therefore, the ripple voltage amplitude of the FB pin is decreased below the FB OVP
threshold. In the 90W reference design, the winding bias voltage provides 1mA (typical) offset
current to the FB pin and the ripple voltage amplitude on the FB pin can decrease to be around half
of that with this bias circuit. Rf2 can be calculated by equation (10), in which VFB is 2.5V reference
voltage.
If the cathode voltage VZD1 is 9.1V, Rf2 is calculated as 6.8kΩ⋅
V ZD1 – V FB
---------------------------- = 1mA
R f2
Equation (10)
Figure 22: Bias Current for Offset Voltage on FB Pin
OCP SW SGND
ISNS
88EM8040
/8041
VIN
VOut
PGND
RS4
CS2
VDD
FB
Opto- Coupler
RS2
CS1
RS5
VZD1
Rf3
CV CC
Rf2
CVDD
C vout
Rf1
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Vref
+
RS3
–
Z D1
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 33
88EM8040/88EM8041
Datasheet
5.3
Current Sensing and Over Current Protection
5.3.1
Current Sensing Through ISNS Pin
The voltage drop on the current sense resistor should be kept very small in order to reduce the
power consumption on the sense resistor. In flyback topology, the drain to source current flows
through the transformer, MOSFET and current sense resistor (Rsen). This is shown in Figure 23. The
average current mode control single stage solution requires two signals of flyback: the peak current
signal to avoid the transformer saturation including a short circuit condition, and the average current
sense signal to achieve the right PFC operation. The voltage drop (Vsen) across resistor (Rsen)
represents the flyback peak current signal. The voltage of (VCS), after RCS and CCS low pass filter,
represents the average current signal of the primary side of the flyback converter.
Figure 23: Current Sensing Circuit
DR2
VDCin
VOUT
Np
Csn
Rsn
NS2
Cin
Vsen
Dsn
Drain
Q1
Rsen
Rcs
Ccs
OCP SW S GND
I SNS
Vcs
88EM8040
VIN
/8041
VDD
P GND
FB
The resistor (Rsen) should be designed such as the example in Table 7 where Rsen is designed for a
90W adaptor. The specification are: output power = 90W, input voltage range = 85-264V, output
voltage = 20V, output current= 4.5A, 30% margin of over current on top of the normal current.
Doc. No. MV-S104983-01 Rev. A
Page 34
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
Current Sensing and Over Current Protection
Table 7:
Current Sensing Circuit
Input Power
Pin
90W
Minimum input voltage
Vinmin
85V
Maximum average input
current
I inmax =
1.49A
P in
2 × --------------V inmin
Over current threshold
Zone 1
VIOVERTH1
0.391V
Over current margin
Imargin
30%
Current sensing resistor
calculation
V IOVERTH1
R sns = ---------------------------------------------------i inmax × ( 1 + I m arg in )
0.2Ω
Current sensing resistor
selection
Rsns
0.2Ω
Table 8 shows the reference value of the current sensing resistor. In the practical design, the current
sensing resistor value could be fine tuned around the value shown in the table based on the specification
and the primary inductance of the flyback transformer.
Table 8:
5.3.2
Current Sensing Resistor Selection Reference
Input Power (W)
36
72
90
120
Current Sensing Resistor (Ω)
0.40 - 0.45
0.20 - 0.27
0.15 - 0.20
0.12 - 0.15
Average Current Signal and Over Power Limitation
To convert flyback peak current into an average current signal, an RC filter is required. Figure 24
shows how adding two more components will result in an average current signal. This average
current signal, VCS is fedback onto the ISNS pin and used to achieve a sinusoidal current waveform
by an internal current control loop. It is also used to achieve power limitation. The corner frequency
of the RC filter is recommended approximately 1/10~1/6 of the switching frequency. Rcs is
recommended as the value of 187Ω for the purpose of blocking negative and surge voltages. A
single stage PFC operates at 120kHz (typical), Ccs is designed as 47nF which results in a corner
frequency of 18kHz. The internal IC block is designed to perform the over power limitation as shown
in the electrical characteristics table. The corner frequency of the low pass filter is designed as;
1
f corner = ----------------------2πR cs C cs
Equation (11)
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 35
88EM8040/88EM8041
Datasheet
5.3.3
Cycle by Cycle Current Protection through OCP Pin
In order to get the cycle by cycle current protection to avoid the transformer saturation, a circuit with
a low base to emitter parasitic capacitance NPN transistor is recommended in the design, as shown
in Figure 24. The sensing voltage through Rsen should trigger and turn on the transistor of Q2 during
the over current condition. Q2 then pulls the OCP pin to low and turns off the gate signal to the
external MOSFET. In order to get proper protection, a -2mV/°C (typical) temperature coefficient of
(Vbe) should be considered. The lowest voltage (Vbe) will be set to the junction temperature of 80°C.
Figure 24: Current Sensing and Cycle by Cycle Over Current Protection Circuit
DR2
VDCin
VOUT
Np
Csn
Cin
Rsn
NS2
Q2
Vsen
Dsn
Q1
R1
R2
Rsen
Drain
Csen
Rcs
Ccs
OCP SW S GND
I SNS
Vcs
VIN
88EM8040
/ 8041
VDD
FB
Figure 25: Current Sensing and Cycle by Cycle Over Current Protection Waveforms
D
D
GND
Vcs
avg
cs
V
Vcs
LEB
(Leading Edge
current)
avg
Vsen
Vsen
Vsen
Vcsavg
avg
Vsen
Power limit
OCP
OCP
Doc. No. MV-S104983-01 Rev. A
Page 36
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
Current Sensing and Over Current Protection
V be ≅ 0.65V – 2mV × ( 80 – 25 ) = 0.54V
The highest Vbe voltage will be set to the junction temperature of -25°C.
Equation (12)
V be ≅ 0.65V – 2mV × ( – 25 – 25 ) = 0.75V
Equation (13)
The voltage Vbe is supposed to have some tolerance margin to select the resistor of Rsen without
any unpredicted cycle by cycle over current protection. The recommended equation is:
0.50V
R sen ≤ ---------------peak
I ds
Equation (14)
The minimum saturation current point of Ilim for the transformer should satisfy:
0.75V
I lim = -------------R sen
Equation (15)
Ilim should have enough margins considering transformer saturation condition at lower ambient
temperature.
R1 and R2 should be selected properly in Figure 24, in order to make the cycle by cycle current
limiting work correctly. R1 and R2 act as voltage dividers to setup the right current limitation
threshold. Actually R2 also works as controlling base current of that transistor, the same time, R1
works to discharge the parasitic capacitance of that transistor. In the practical design, the R1 and R2
need to choose properly based on the power rating of the system. The value of R1 is recommended
as 500~2KΩ and R2 as 500~2kΩ.
Please note that a small value of the capacitor parallel with the Rsns resistor is very helpful to filter
the noise in order to guarantee this OCP circuit to function properly. When the MOSFET turns on,
external COSS of the MOSFET starts discharging. This causes switching loss increases and makes
the leading edge current. Figure 25 shows that this current creates unwanted over current making
the system not function properly. This phenomenon can be avoided by adding one capacitor Csen.
The leading edge current timing is less than 300nS (typical). Csen can be calculated as;
1
f sen = ---------------------------- ≈ 1MHz
2πR sen C sen
Equation (16)
Csen is recommended to have a value of 0.22μF/25V.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 37
88EM8040/88EM8041
Datasheet
5.3.4
Peak Current and Average Current Relationship
The relationship between the flyback peak and the average current signals are described in the
following equation. Figure 25 explains this in detail.
Current sensing signal across Rsen resistor is calculated as
V sen = R sen × I ds
Equation (17)
The average current sensing signal during MOSFET switching on is
V sen
ΔI ins
= V sen – R sen -----------2
avg
Equation (18)
The switching frequency peak to peak ripple is
V line ⋅ D
ΔI ins = -------------------Lm ⋅ fs
Equation (19)
The average current sensing signal during the whole switching cycle is
V cs
avg
= V sen
avg
×D
Equation (20)
Doc. No. MV-S104983-01 Rev. A
Page 38
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Design and Applications Information
SW Pin to MOSFET Gate
5.4
SW Pin to MOSFET Gate
The 88EM8040/88EM8041 provides a maximum 2A drive current, which is the strongest driver
capability in comparison with the other similar part on the market. A default resistor of 10Ω is
designed to go between the SW pin and the gate of the external MOSFET. The gate driver loop is
subject to fast rise and the layout trace should be kept as short as possible in order to minimize the
parasitic inductance, as shown in Figure 26.
Figure 26: SW Pin Layout Guidelines
DR2
VDCin
VOUT
Np
Csn
Rsn
NS2
Dsn
Rgate Q1
Drain
Keep this trace as short
as possible in layout
OCP SW SGND
ISNS
88EM8040
/8041
VIN
VDD
5.5
PGND
FB
VDD, Signal Ground (SGND) and Power Ground
(PGND)
VDD is the IC power supply pin. It has a typical input voltage value of 12V and a maximum operating
voltage of 16V. A Zener clamp circuit of 16V is recommended in order to guarantee that the voltage
on VDD will not go any higher than 16V. The IC begins to function when VDD powers on at 12V.
Once the IC powers on, it keeps functioning as long as the VDD is higher than VDD_UVLO, which is
7V (typical). In a practical design, an electrolytic capacitor 220μF (typical) is recommended to
connect between VDD and ground in order to retain the IC functionality during startup. That
capacitor will need to keep the VDD higher than 7V before the bias transformer winding takes over
and provides enough energy for the power IC.
A 0.01-0.1μF ceramic capacitor is strongly recommended to be placed between the VDD and IC
ground with the layout trace as close to the IC as possible. This capacitor is used for decoupling the
noise to VDD and clamping the VDD voltage during the switching of the internal driver circuit.
SGND is directly connected to the system ground by a Kelvin connection trace. The system ground
is the source of the MOSFET, as shown in Figure 27. PGND connects to the system ground
separately and can not share the same trace with SGND. This is due to pulse current on PGND
while driving the external MOSFET on and off. This pulse current produces pulse voltage drops on
the PGND trace and may cause the current sensing signal to be distorted if the SGND shares the
same trace.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 39
88EM8040/88EM8041
Datasheet
Figure 27: VDD Decoupling Capacitor and Ground Layout Guidelines
DR2
VDCin
VOUT
Np
Csn
Rsn
NS2
Dsn
Rgate Q1
Drain
Using Kelvin sensing connection for
SGND with separate trace from PGND
OCP SW SGND
ISNS
VIN
88EM8040
/8041
FB
PGND
C
Keep this trace right beside
IC and as short as possible
VDD
Doc. No. MV-S104983-01 Rev. A
Page 40
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
October 5, 2009, Preliminary
Copyright © 2009 Marvell
Document Classification: Proprietary
T101B
2
2
1
1
C109
100uF
R120
20K
ZD102
9.1V
ZD106
15V
4-
R129
1K
ZD101
18V
R130C
2.5M
R130B
2.5M
R130
2.5M
C108 C107
470uF 0.1uF
50MH
LF2
ZD107
18V
C110
0.1uF
Q103
2N7002
R305
9.1M
CX1
0.47uF
R117 R115 Q107
1.1K 5.1K BCX54
ZD105
6.2V
CY1
1nF
R304
9.1M
10MH
LF1
R303
9.1M
D103
US1D
R302
9.1M
R114
5.1K
GTD 1
501
VARA1
240V
4A250V
R301
9.1M
Socket
N
L
J1
R106A
620K
R106B
620K
R106C
620K
Q108
MMBT4403
D104
1N4148
R107 D101 R116
802 1N4148 2K
NTC2
100k
t
L101
50uH
C105
1uF
R127
12K
R108
C103 18K
220pF
BD1
GBL406
1
Q102
STD1NK60
R132
100K
3
2
+
ISNS
Q109
MMBT4401
R128
12K
R122
12K
3
4
C102
47nF
1
R110
300
R111
1.21K
U200B
LTV817B
5
C104
0.1uF
FB
SW
8
C120
4.7nF
R112
5.1K
2
R105
5.1
R135
820K
ZD104
0.1uF
R118
360
SGND PGND
2
C106
0.22uF
R101
0.15
88EM8041
IC101
VDD
7
t
NTC1
10K
SDI/FSET
VIN
R109
300K
6
4
3
R104
187
R134
820K
Q105
MMBT4401
R119
1.1K
C101
0.68uF
R133
1M
3
1
R103
5.1
Q101
IPB60R199
D120
US1J
R125
100K
R126
100K
2
R207
2K
Q106
R102
MMBT4403 10K
R124
100K
R123
100K
9
5
6
C220
1nF
ZD201
6.8V
7
C211
0.1uF
D200
VF40120C
10
VCC
R209
2K
Cvout
GND
Cv-
Cc+
Cc-
Vref
D220
ES1002FL
10
R221
R220
2
D201
VF40120C
2
TSM1014
IC200
Ccout
1
3
1
3
C212
4.7uF
5
D202
1N4148
U200A
LTV817B
R206
11K
2
1
R208
2K
T101A
250uH
8
4
3
2
1
+
+
+
+
R200
15K
C210 R204 C209 R201 C207
0.1uF 1.5K 0.1uF 1K
10nF
R203
30K
RS200
0.01
R202
1K
C201
C202
C203
C204
C206
2700uF 2700uF 2700uF 2700uF 0.1uF
C208
0.1uF
VO-
VO+
5.6
6
FS1
90W/20V Signal Stage PFC Adaptor Schematic and Bill of Materials (BOM)
Design and Applications Information
90W/20V Signal Stage PFC Adaptor Schematic and
Bill of Materials (BOM)
Figure 28: 90W/20V Single Stage PFC Adaptor Schematic
Doc. No. MV-S104983-01 Rev. A
Page 41
88EM8040/88EM8041
Datasheet
THIS PAGE INTENTIONALLY LEFT BLANK
Doc. No. MV-S104983-01 Rev. A
Page 42
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Mechanical Drawings
6
Figure 29: 8-Lead SOIC Mechanical Drawing
Document Classification: Proprietary
Mechanical Drawings
Copyright © 2009 Marvell
October 5, 2009, Preliminary
6.1
„
All dimensions in mm.
See Section 7, Part Order Numbering/Package Marking, on page 45 for package marking and pin 1
location.
Mechanical Drawings
„
Mechanical Drawings
Page 43
Doc. No. MV-S104983-01 Rev. A
Notes:
88EM8040/88EM8041
Datasheet
THIS PAGE INTENTIONALLY LEFT BLANK
Doc. No. MV-S104983-01 Rev. A
Page 44
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
Part Order Numbering/Package Marking
Part Order Numbering
7
Part Order Numbering/Package Marking
7.1
Part Order Numbering
Figure 30 shows the part order numbering scheme. For complete ordering information, contact your
Marvell FAE or sales representative.
Figure 30: 88EM8040/88EM8041 Sample Ordering Part Number
88EM804X xx–SAG2C000–xxxx
Custom code (optional)
Part number
Custom code
Custom code
Temperature code
C = Commercial
Custom code
Environmental code
2 = Green Halogen Free
Package code
The standard ordering part number for the respective solution is shown in Table 9.
Table 9:
88EM8040/88EM8041 Part Order Options1
P a c k a g e Ty p e
Part Order Number
8-Pin SOIC
88EM8040xx-SAG2C000
8-Pin SOIC
88EM8040xx-SAG2C000-T (Tape and Reel)
8-Pin SOIC
88EM8041xx-SAG2C000
8-Pin SOIC
88EM8041xx-SAG2C000-T (Tape and Reel)
1. Please note that the 88EM8040 device is 60kHz and the 88EM8041 device is 120kHz.
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 45
88EM8040/88EM8041
Datasheet
7.2
Package Markings
Figure 31 shows a typical package marking and pin 1 location.
Figure 31: 88EM8040/88EM8041 Package Marking
MRVL
Marvell company abbreviation
804X
Abbreviated part number
XXXX = 4 character abbreviated part number
YWWG
Pin 1 location
Date code and assembly house code
Y = last digit of year
WW = work week
G = assembly house code
Note: The above example is not drawn to scale. Location of markings are approximate.
Doc. No. MV-S104983-01 Rev. A
Page 46
Copyright © 2009 Marvell
Document Classification: Proprietary
October 5, 2009, Preliminary
A
Table 10:
Revision History
Revision History
D o cu m e n t Ty p e
D o c u m e n t R e v is i o n
Release
8040/41 Rev. A
•
•
•
•
Revised EC table with new values.
Reworked Application and Design Section
Revised Mechanical Drawing
Updated Part Ordering
Release
8041 Rev. –
First Release
Copyright © 2009 Marvell
October 5, 2009, Preliminary
Doc. No. MV-S104983-01 Rev. A
Document Classification: Proprietary
Page 47
Back Cover
Marvell Semiconductor, Inc.
5488 Marvell Lane
Santa Clara, CA 95054, USA
Tel: 1.408.222.2500
Fax: 1.408.752.9028
www.marvell.com
Marvell. Moving Forward Faster