About ST
Products
Applications
Support
Buy
News & Events
ST Worldwide
Contact Us
Login
Application Notes
|
Industrial
|
Motor Control
|
8-bit Microcontrollers
|
ST7 - 8-bit Microcontrollers
PFC for ST7MC starter kit
Application Note
Format:
(218 kb)
or
(24 kb)
Last Updated: 17/07/2007
Pages: 20
Related Data Briefs
Low voltage motor control demonstration kit based on the ST7MC2S4 and STS8DNH3LL
Related Datasheets
8-bit MCU with nested interrupts, Flash, 10-bit ADC, brushless motor control, five timers, SPI, LINSCI"
Raw Ascii Text
- (
Hide
)
(Unformatted textual content of the document used by search engines)
AN1953 Application note
PFC for ST7MC starter kit
Introduction
The aim of this Application Note is to give an example of how to use the ST7MC microcontroller to implement the Power Factor Correction (PFC) inside a motor control application. The ST7MC microcontroller is provided with a Motor Control Peripheral which has been developed to implement motor control function for Induction motors and Permanent Magnet Synchronous motors. The motor control peripheral leaves the microcontroller resources free to perform the power factor correction. The power factor correction technique utilized is called "transition mode". The hardware used to realize the system is the ST7MC Starter Kit plus an additional external power board called "Add On". In this application note, theoretical information about the PFC control method is given, in addition to an explanation of the software routine able to manage the PFC stage and the calculation of the Add On components. The reader can find extra information about the motor control related routines the application note AN1904.
AN1953
Rev 2
1/20
http://www.st.com 20
PFC for ST7MC Starter Kit
Contents
1 Theory about the PFC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1 Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2 3
Starter kit approach . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Firmware description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3.1 3.2 Flowchar t . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 PFC software description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4
Hardware description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
4.1 Power stage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
4.1.1 Power section design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
5 6 7 8
Schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 References and related materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
2/20
PFC for ST7MC Starter Kit
1 Theory about the PFC
1
Theory about the PFC
This application note focuses on the management by a microcontroller of the boost stage to obtain a power factor corrector (PFC) working in transition mode. Of course to do this job the microcontroller should have a timer with a special feature. A block diagram of the application is shown in Figure 1. Figure 1. Block diagram
BOOST Stage LOAD
DRIVER uC Supply ST7MC Volt Measure
1.1
Description
With this method, the boost inductor works on the boundary between continuous and discontinuous mode. In this operation mode there is a high peak current which means that this kind of approach could be used for power below 600W. Here, the system works with fixed ON-time and variable frequency and functions as follows: The main supply is rectified by the bridge and the energy is stored in the transformer during the turn-on period of the mosfet. This time interval is called Ton and must be calculated by the Micro according to the Vout value, the input voltage and the load. To simplify the algorithm, just the output voltage is measured and the difference (error) between the desired values (400V) and the actual value is calculated. This error is multiplied by a constant to obtain the right correction value. The measured voltage value is the average of eight ADC conversions. The turn-off time of the mosfet is called Toff and is fixed by the circuit. This means the inductor discharges all its own energy to the output stage until its current goes to zero. In this condition, the drain Voltage will go to the Vin voltage and an oscillation due to the MOS capacitance is added to this voltage. In order to reduce the commutation losses, the MOS must be turned ON when the Drain voltage reaches the minimum. To detect this condition the secondary winding of the transformer is used. In fact, in this secondary winding is a square wave with zero mean value which is made up of a negative signal during the Ton and a positive signal during the Toff. To adapt this signal to the digital world of a microcontroller a resistor to limit the current plus the internal clamping diodes have been used to obtain a square TTL waveform.
3/20
1 Theory about the PFC
PFC for ST7MC Starter Kit
So, finally, a TTL square wave is obtained on the microcontroller pin which is used by the timer peripheral to restart the counter cycle and fix the counter period. For the timer, it's important to note that if there isn't a load variation and/or a variation of the input voltage, it could work as a standalone circuit without any computational time required to the micro. In fact, if the zero current condition (ZCD) is missed the timer will restart at the minimum frequency through a software routine. Of course the availability of the micro makes a lot of features possible simply by modifying some parameters and it also allows a particular software routine to be used to improve the control method. The output of the PWM timer is connected to the TD220 driver that drives the MOS of the boost stage.
4/20
PFC for ST7MC Starter Kit
2 Starter kit approach
2
Starter kit approach
To implement the PFC with the ST7MC starter kit we developed a power board "Add On" that realizes the control of the Bus voltage with a boost topology. The Power Add On is connected to the mains and provides the Bus voltage for the starter kit. The Power Add On requires two connections with the starter kit. One is the PWM generated by the microcontroller coming from the starter kit and the second sends the zero crossing signals to the starter kit. The Add On power board needs a supplementary 15 Volts to supply the driver, which can be provided by the starter kit (J16). The starter kit is then connected to the motor by the wire for the phases and with the tachometer signal if required. The Add On power board provides the rectified and controlled voltage bus for the starter kit. The starter kit board has been modified as in Figure 2
the bridge D4 has been removed and correctly short-circuited (pin 1-2; pin 3-4) the capacitances C1 and C2 have been removed the NTC1 has been removed and short-circuited the fusible F1 has been removed and short-circuited Modifications to be performed in the Starter Kit
J12 A B 1 2 3 4 5 MOTOR
Figure 2.
MSTBA2,54/5-G-5,08 J3 1 2 3 GMKDS 3/3-7,62 90/140VAC OR 180/260VAC TP13 5X20(type KELSTONE) F1 10A R 43 R44 5.6K 1/4W OR 1/4W Phase C D 16 STTA106U R49 5.6K 1/4W Phase B D17 STTA106U R 53 R51 1K2 1/4W R54 R45 1K2 1/4W J11 R50 OR 1/4W C B A 1 2 3 4 5 6 7 MOTOR PHASES Z3 BZW50-120 SOLDER FOR 110VAC Z2 BZW50-120 TP6 NTC 1 SG170(4R)
Mounted on 17C/W AAVID Thermalloy heatsink
4
D4 STBR608
2 1 3
C1 4.7nF Y C2 4.7nF Y
C11 100nF 400V Z4 BZW50-100 1 W2 2
TO SOLDER
The modification has been performed also on the value of some component in order to work in safe with a bus voltage of 400-500 Volt. So the following components have been substituted: (see Figure 3)
C12 and C13 bulk capacitors have been replaced with one of 470uF 450Volt The transil Z2 and Z3 has been replaced with BZW50 -180 R1 and R2 resistors have been replaced with 68K - 1W C20 capacitor has been replaced with 33nF - 600V
5/20
2 Starter kit approach
PFC for ST7MC Starter Kit
Modifications to be performed in the Starter Kit
R20 6.2K C13, C12: 470uF 450V
C 11 100nF 400 V Z4 BZW50-100 W2 C13 1000 uF 200V R2 47 K 1W
Figure 3.
R1 6 470 K HV Bus
C20:33nF 600V
1
2
TO SOLDER
R17 470K
B60HDFP T4
P hase B
Z2, Z3: BZW50180 transil
Z2 BZW50-120 C12 1000uF 200V R1 47K 1W R20 12K TP11
C20 33nF 400V R21 0.047R 4W 7NB60HDFP T5 TP14 TP17
Z3 BZ W 50-120
FOR 110VAC
R1, R2: 68K - 1Watt
To get the Bus voltage value a voltage divider with R16-R17 and R20 is used. To get 5 Volts as a maximum voltage for the AD converter with the new Bus voltage max value, R20 must be replaced with a 6.2K resistance. To connect the Power Add On board with the starter kit, use two control cables, one to communicate the PWM for the Add on coming from starter kit and one to get the zero crossing from the Add on to the starter kit. The connection of the zero crossing cable is critical. The shunt resistor has been connected near the pin of the starter kit to avoid a capacitive parasite effect of the cable acting as a filter for the zero crossing signal and a capacitor of 12pF has been added to filter the noise. To generate the PWM for the PFC, the Timer B of the micro is used. The PWM signal of the PFC Power Add On is connected to the OCMP1_B pin of the micro (J10 Pin 3) and the Zero Crossing signal of the Add On reaches the ICAP1_B pin of the micro (J10 Pin 7). The PE2 pin it is connected with ICAP1_B, because it is used to force the reset of PWM when the ZCD signal is missed. This could happen for example when the instantaneous input voltage is too low to energize the inductor. The Vout of the Add On is the Mains for the Starter Kit board so must be connected to the Pin 2 and Pin 3 of J3. The ground signal is connected directly from the ground of the micro to the ground of the driver in the Add On. The connections are depicted in Figure 4.
6/20
PFC for ST7MC Starter Kit
Figure 4. Connection between Starter Kit and Add On power board
J3 1 2 3
2 Starter kit approach
+ Vout PWM Zero crossing Signal GND PFC Power Add On
8 7 2mm Linebar 2
J10
1 1 2 3 4 5 6 7 OCMP1_B/PE1 ICAP2_B/PE2 ICAP1_B/PE3 Vpp MCO0 MCO1
Signal GND ST7MC Starter Kit
7/20
3 Firmware description
PFC for ST7MC Starter Kit
3
3.1
Firmware description
Flowchart
Figure 5 shows the flowchart of the ART interrupt service routine that is called every 1ms. Figure 5. ART Interrupt service routine for PFC ART Interrupt every 1ms
PFC Running Yes Vout > OVERVOLTAGE Yes PFC Over voltage Stop PWM
Delay20 = 0 Yes Each 20ms PFC Ton Adjust
PFC TOTONINCREASE Yes PFC Running Start PWM Number Of Ton Increase = 0 Counter Ton++ Counter Ton >= MAXRESTART PFC NoRestartTon Stop PWM Counter Ton = 0
PFC Over voltage Vout < MIN_VOUT Yes PFC Running Restart PWM
8/20
PFC for ST7MC Starter Kit
Figure 6 shows the main loop. Figure 6. Main Flowchart
PFC_Init PFC_Timer_Init
3 Firmware description
Main Loop Vout = ADC_GetVout Each Loop Cycle PFC_Run
Motor Control Routine
Figure 7 shows the PFC_RUN function. Figure 7. PFC_RUN Flowchart
Vout>OVERVOLTAGE Yes PFC Over voltage Stop PWM
9/20
3 Firmware description
PFC for ST7MC Starter Kit
Figure 8 shows the PFC_TON_ADJUST routine. Figure 8. PFC_TON_ADJUST
No PFC Running PWM Start Error = Kp * (Vout400 - Vout) Error > 3 Yes Error = 3 Error = Kp * (Vout - Vout400) Error > 3 Yes Error = 3 Vout > Vout400 Yes
Yes
Error > Ton Ton = Ton - Error Ton < MIN_TON Yes Ton = MIN_TON
Ton = Ton + Error Ton > MAX_TON Yes Ton = MAX_TON Number Of Ton Increase++
Ton = MIN_TON
Number Of Ton Increase > MAXTONINCREASE
Yes PFC TOTONINCREASE Stop PWM
3.2
PFC software description
This paragraph contains a description of the part of the software related to the PFC. The complete explanation of the software is beyond this AN. For a more detailed explanation of the motor control software library please refer to the application note AN1904. The modules related to PFC are the following:
Pfc.c Pwmar t.c (Partially) Timer.c
The file Pfc.h contains some parameters that can be customized by the user according the application. At the beginning of the main module (main.c) there is the initialization of the PFC variables and timer parameters.
PFC_Init(); PFC_TIMER_Init(); SetBit(TBCR2,TBCR2_OC1E);
Then in the main loop the only two tasks performed are the acquisition of the Bus voltage Vout
10/20
PFC for ST7MC Starter Kit
Vout=ADC_GetVout();
3 Firmware description
and the check of over-voltage detection condition, performed in the procedure PFC_Run. In the Pfc.h file are defined different status of the PFC system:
#define #define #define #define #define #define #define #define PFCOFF 0x00 /* no fault*/ TOOTONINCREASE 0x01 /* Too Ton increase*/ OVERVOLTAGEFAULT 0x02 /* OverVoltage detect for MAXOVERVOLTAGE time*/ PFCRUNNING 0x04 LOWVOLTAGEFAULT 0x10 /* Low voltage on DC BUS */ NORESTARTTON 0x20 /* No restart after OverVoltage */ NORESTARTOV 0x40 /* No restart after OverVoltage */ EXTBREAK 0x80 /* External break event */
The other PFC routines are called inside the ART interrupt. This is used as a time base for all time-related issues of the motor control routine and it is generated every 1 ms. The PFC Ton Adjust routine it is called each 20 ART interrupts (20 ms) if the status of the system is PFC Running and this routine is used to calculate and set the new Ton duration.
If the status of the system is TOOTONINCREASE it means that the PWM is stopped because there was too much successive increase of the Ton caused for example by an overload condition. In this case the software tries to restart the PFC clearing the variable "Number Of Ton Increase" and increasing the variable "Counter Ton". If "Counter Ton" reaches the MAXRESTART value the status will be changed in NORESTARTTON and the PWM will be stopped. If the status of the system is OVERVOLTAGE and Vout is below MIN_VOUT, during the ART interrupt the software restarts the PWM.
PFC Ton adjust
This routine is dedicated to the control of the Bus voltage by means of the Ton duration variable. It is the only PFC-related routine that requires some CPU load. It is executed every 20ms and its duration is 15 microseconds, so the CPU load is 0.075%. The Bus voltage is scaled by a factor 0.0065 through a voltage divider. Then the A/D conversion introduces another factor of 255/5 so to convert the Voltage bus value expressed in volts into the value stored inside the software we can use the formula:
V o u t = Vbus [ Volt ] × 0.334
rounded down to the nearest integer. So we have the following parameters:
#define VBUS 140 // = 0.334 * VBus #define MIN_VOUT 127 #define OVER_VOLTAGEDC 155 //
VBUS: is the target bus voltage. OVER_VOLTAGEDC: if the bus voltage exceeds this value the firmware determine an over voltage. In this case it stops the PWM and the PFC_STATUS will be changed in PFCOVERVOLTAGE. MIN_VOUT: if the voltage bus drops under this value after an over voltage, the system restarts the PWM generation and the PFC_STATUS will be changed in PFCRUNNING.
11/20
3 Firmware description
PFC for ST7MC Starter Kit
The error is the difference between the actual value of the voltage bus (Vout) and the target voltage (VBUS) multiplied by a factor of Kp. The error is subtracted from the actual value of the Ton. The value of Ton is the number of Timer B steps. Ton is inferiorly limited to MIN_TON value and superiorly to MAX_TON. If Ton is set to the maximum value the counter "Number Of Ton Increase" is increased by one, if this variable reaches the value MAXTONINCREASE the system PFC status is changed into TOOTONINCREASE and the PWM it is stopped.
Timer.c
Timer.c module is used to setup and control the generation of the PWM control signal. To generate this signal it is used the Timer B peripheral in one pulse mode. The output pin OCMP1_B is used as PWM control signal. The Timer B frequency is fixed to 4 MHz so each step is 0.25s. Ton duration sets the number of steps in which the OCMP1_B is in high state (see Figure 9). Figure 9. Ton time duration of the PWM
OCMP1_B pin Timer B block = 4 MHz T=0.25 s
Ton=4 T=1 s
t
TimB_init (Ton) is used to set up the Timer B to generate the pulse. Ton sets the number of steps of the timer in which the timer output is high. TimB_star t() is used to start the timer. TimB_stop() is used to stop the timer.
Vector.c
TIMB_Interrupt is generated when Timer B reaches the value TBOC2R = 0x0F9B (After 1 ms the restart of the Timer is forced using PE2) this interrupt happens only in the zero current event it is not correctly detected for example when the input voltage it's near the 0V. At each of this interrupt if the Ton < MIN_TON the output of the PWM is switched off this to avoid the a too short pulse it's generated on the gate of the mos. Else if Ton >= MIN_TON the TBOC1R is set to (Ton - 5) to set the pulse of PWM equal to Ton step of timer frequency (4 Mhz)
12/20
PFC for ST7MC Starter Kit
3 Firmware description
Figure 10. Restarting the PWM if maximum value is reached before the ZCD TBOC2R
Ton
TBOC1R
13/20
4 Hardware description
PFC for ST7MC Starter Kit
4
4.1
Hardware description
Power stage
The criteria used for the design of the power stage are extracted from the AN966 "L6561, Enhanced Transition Mode Power Factor Corrector". The steps followed have been to fix the operating conditions and then to dimension the single part of the design to these.
Mains voltage range: Virms(min) Virms(max) Output voltage: Vout Output power: Pout Minimum switching frequency: Fsw Maximum output voltage ripple: Vout
4.1.1
Power section design
Input Bridge
The input diodes bridge can use standard slow recovery, low-cost devices. The quantities to consider will be just the input current (Irms), the maximum peak mains voltage and the thermal data of the diodes.
Input capacitor
The input high frequency filter capacitor (Cin) has to attenuate the switching noise due to the high frequency inductor current ripple. High values of Cin alleviate the burden to the EMI filter but cause the power factor and the harmonic contents of the mains current to worsen, especially at high line and light load. On the other hand, low values of Cin improve power factor and reduce mains current distortion but require heavier EMI filtering and increase power dissipation in the input bridge. It is up to the designer to find the right trade-off in their application.
Output capacitor
The output bulk capacitor (Co) selection depends on the DC output voltage, the admitted over voltage, the output power and the desired voltage ripple. The 100 to 120Hz (twice the mains frequency) voltage ripple (Vout= 1/2 ripple peak-to-peak value) is a function of the capacitor impedance and the peak capacitor current.
I0 P out Cout --------------------- = ------------------------------4 f V out 4 f V out V out
Boost inductor
Designing the boost inductor involves several parameters and different approaches can be used.
14/20
PFC for ST7MC Starter Kit
4 Hardware description
First, the inductance value must be defined. The inductance (L) is usually determined so that the minimum switching frequency is greater than the minimum switching frequency that avoid audible noise, this value it's fixed by software equal to 10kHz to ensure a correct TM operation. Assuming unity PF, it is possible to write:
L IL k T on = ------------p-----2 V Irms
L I Lpk sin ( ) T off = -------------------------------------------------V out 2 V Irms sin ( )
So it is possible to calculate the value of the inductor as a function of the minimum switching frequency.
V 2 s ( V ut 2 V Irms ) r L = ----i---m----------o-------------------------------- 2 F SW P i V out
POWERMOSFET
The choice of the MOSFET concerns mainly its Rds, which depends on the output power, since the breakdown voltage is fixed just by the output voltage, plus the over voltage admitted and a safety margin.
Boost diode
The boost freewheeling diode will be of a fast recovery type.
Design parameters used in this AN:
Input voltage: 176V..264V Output regulated voltage: 400V Output power: 600W Minimum switching frequency: 80kHz Full load output ripple: 4%
Po t I rms(max) = ----------u----- = 3.4A V in(min)
Input Bridge: Generic 10A Bridge Input Capacitor: 0.22F Output Capacitor 470F 450V Boost Inductor 80H with 29 turns 0.40 mm x 10 in the primary saturation current 10A and 3 turns in the secondary POWERMOSFET P12NK60 BOOST DIODE STTA12
To calculate all these values you can follow the formulas used in the AN966.
15/20
5 Schematics
PFC for ST7MC Starter Kit
5
Schematics
The Add On power stage is depicted in Figure 11. Figure 11. Schematic of Add On power stage
F1 J1 3 2 1 220VAC R1 470k zero current detect VDC+15V VDC+15V D4 1 3 1N4001 Gate Driver VinWaveform TD221 C2 + 200n 400V C3 1uF 25 R8 12 C4 100p R9 15k R10 68k R11 68k R12 0.41 C5 1p R7 47 OCP 1 2 3 4 R2 470k U1 VIN Vcap VOUT Vsup NC GND IN GATE 8 7 6 5 R3 27K R5 47 1 R6 .7 4 R4 4.7 3 D3 1N4001 1 Q1 2 STP12NM50 3 1N4001 D5 3 1 Q2 1 2 1 FUSE 3D1 10A Bridge +4 TRANSFORMER 2 T1 6 1 1 3 STTH106 J3 1 D C1 1n NTC1 2.5 D2 3 1 2
VDC-OUT J2 1 2 3
J4 1 2 CON2
2 STP12NM50 3
16/20
PFC for ST7MC Starter Kit
6 Measurement
6
Measurement
Figures 12 and 13 show the behavior of the PFC in terms of the Boost Inductor Current, the DC Bus Voltage and the Drain Voltage. The operating conditions are:
Vin = 220 V Ac Load = 440 W
Figure 12. DC bus drain voltage
Figure 13. Characteristics of drain voltage and inductor current
17/20
7 References and related materials
PFC for ST7MC Starter Kit
7
References and related materials
1. 2. 3. 4. 5. ST7MC datasheet TD22x datasheet AN966 L6561, Enhanced Transition Mode Power Factor Corrector AN1904 Software library for AC induction motor ST7 Software Library, http://www.st.com/mcu
18/20
PFC for ST7MC Starter Kit
8 Revision history
8
Revision history
Table 1. Document revision history
Date 13-May-2005 16-Jul-2007 Revision 1 2 Changes Initial release Removed references to obsolete products
19/20
8 Revision history
PFC for ST7MC Starter Kit
Please Read Carefully:
Information in this document is provided solely in connection with ST products. STMicroelectronics NV and its subsidiaries ("ST") reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any time, without notice. All ST products are sold pursuant to ST's terms and conditions of sale. Purchasers are solely responsible for the choice, selection and use of the ST products and services described herein, and ST assumes no liability whatsoever relating to the choice, selection or use of the ST products and services described herein. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted under this document. If any part of this document refers to any third party products or services it shall not be deemed a license grant by ST for the use of such third party products or services, or any intellectual property contained therein or considered as a warranty covering the use in any manner whatsoever of such third party products or services or any intellectual property contained therein.
UNLESS OTHERWISE SET FORTH IN ST'S TERMS AND CONDITIONS OF SALE ST DISCLAIMS ANY EXPRESS OR IMPLIED WARRANTY WITH RESPECT TO THE USE AND/OR SALE OF ST PRODUCTS INCLUDING WITHOUT LIMITATION IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE (AND THEIR EQUIVALENTS UNDER THE LAWS OF ANY JURISDICTION), OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. UNLESS EXPRESSLY APPROVED IN WRITING BY AN AUTHORIZED ST REPRESENTATIVE, ST PRODUCTS ARE NOT RECOMMENDED, AUTHORIZED OR WARRANTED FOR USE IN MILITARY, AIR CRAFT, SPACE, LIFE SAVING, OR LIFE SUSTAINING APPLICATIONS, NOR IN PRODUCTS OR SYSTEMS WHERE FAILURE OR MALFUNCTION MAY RESULT IN PERSONAL INJURY, DEATH, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE. ST PRODUCTS WHICH ARE NOT SPECIFIED AS "AUTOMOTIVE GRADE" MAY ONLY BE USED IN AUTOMOTIVE APPLICATIONS AT USER'S OWN RISK.
Resale of ST products with provisions different from the statements and/or technical features set forth in this document shall immediately void any warranty granted by ST for the ST product or service described herein and shall not create or extend in any manner whatsoever, any liability of ST.
ST and the ST logo are trademarks or registered trademarks of ST in various countries. Information in this document supersedes and replaces all information previously supplied. The ST logo is a registered trademark of STMicroelectronics. All other names are the property of their respective owners.
2007 STMicroelectronics - All rights reserved STMicroelectronics group of companies Australia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of America www.st.com
20/20
Document Number: 10426
(218 kb)
