NS32FX211

NS32FX211 Microprocessor Compatible Real Time Clock May 1993 NS32FX211 Microprocessor Compatible Real Time Clock General Description The NS32FX211 is fabricated using low threshold CMOS technology and is designed to operate in bus oriented microprocessor systems where a real time clock and calendar function are required The on-chip 32 768 kHz crystal controlled oscillator will maintain timekeeping down to 2 2V to allow low power standby battery operation Features Y Y Y Y Y Applications Y Y Y Y Y Y Low power standby operation (10 mA at 2 2V) 16-pin DIP and 20-pin PLCC Timekeeping from tenths to seconds to tens of years in independently accessible registers Leap year register Hours counter programmable for 12 or 24-hour operation Fully TTL CMOS compatible Fax machines Laser printers Word processors Data logging Industrial process control Connection Diagrams Dual-In-Line Package PCC Package TL F 11011 – 2 TL F 11011 – 1 Top View FIGURE 1 Order Number NS32FX211N NS32FX211V See NS Package Number N16A or V20A TRI-STATE is a registered trademark of National Semiconductor Corporation C1995 National Semiconductor Corporation TL F 11011 RRD-B30M105 Printed in U S A Absolute Maximum Ratings (Note 1) Operating Conditions Operating Supply Voltage Standby Mode Supply Voltage DC Input or Output Voltage Operating Temperature Range Min 4 75 22 0 0 Max 5 25 55 VDD 70 Units V V V C If Military Aerospace specified devices are required please contact the National Semiconductor Sales Office Distributors for availability and specifications DC Input or Output Voltage DC Input or Output Diode Current Storage Temperature (TSTG) Supply Voltage (VDD) Power Dissipation (PD) Lead Temperature (Soldering 10 seconds) b 0 3V to VDD a 0 3V g 5 0 mA b 65 C to a 150 C 6 5V 500 mW 260 C T e 0 C to a 70 C unless otherwise stated Min 20 08 IOH e b20 mA IOH e b1 6 mA IOH e b20 mA (In Test Mode) IOL e 20 mA IOL e 1 6 mA VIN e VSS (Note 2) VIN e VSS (Note 2) VIN e VSS (Note 2) VOUT e VDD All VIN e VCC or Open Circuit VDD e 2 2V (Standby Mode) VDD e 5 0V (Static Mode) b5 b5 b5 Electrical Characteristics VDD e 5V g 5% Symbol VIH VIL VOH VOH VOL IIL IIL IIL IOZH IDD Parameter High Level Input Voltage (except XTAL IN) Low Level Input Voltage (except XTAL IN) High Level Output Voltage (DB0–DB3) High Level Output Voltage (INT) Low Level Output Voltage (DB0–DB3 INT) Low Level Input Current (AD0–AD3 DB0–DB3) Low Level Input Current (WR RD) Low Level Input Current (CS) Output High Level Leakage Current (INT) Average Supply Current Conditions Typ Max Units V V V V V VDD b 0 1 37 VDD b 0 1 01 04 b 90 b 200 b 570 V V mA mA mA mA 20 4 5 10 1 10 mA mA pF pF CIN COUT Input Capacitance Output Capacitance (Outputs Disabled) 10 Note 1 Absolute Maximum Ratings are those values beyond which damage to the device may occur All voltages referenced to ground unless otherwise noted Note 2 The DB0–DB3 and AD0–AD3 lines all have active P-channel pull-up transistors which will source current The CS RD and WR lines have internal pull-up resistors to VDD 2 AC Switching Characteristics READ TIMING DATA FROM PERIPHERAL TO MICROPROCESSOR VDD e 5V g 5% CL e 100 pF Commercial Specification Symbol Parameter Min tAD tCSD tRD tRW tRA tCSH tRH tHZ Address Bus Valid to Data Valid Chip Select On to Data Valid Read Strobe On to Data Valid Read Strobe Width (Note 3 Note 7) Address Bus Hold Time from Trailing Edge of Read Strobe Chip Select Hold Time from Trailing Edge of Read Strobe Data Hold Time from Trailing Edge of Read Strobe Time from Trailing Edge of Read Strobe Unitl O P Drivers are TRI-STATE 300 0 0 70 160 250 TA e 0 C to a 75 C Typ 390 140 140 Max 650 300 300 DC ns ns ns ns ns ns ns ns Units WRITE TIMING DATA FROM MICROPROCESSOR TO PERIPHERAL VDD e 5V g 5% Commercial Specification Symbol Parameter Min tAW tCSW tDW tWW tWCS tWA tWD tAWS Address Bus Valid to Write Strobe O (Note 4 Note 6) Chip Select On to Write Strobe O Data Bus Valid to Write Strobe O Write Strobe Width (Note 6) Chip Select Hold Time Following Write Strobe O Address Bus Hold Time Following Write Strobe O Data Bus Hold Time Following Write Strobe O Address Bus Valid before Start or Write Strobe 400 250 400 250 0 0 100 70 35 20 TA e 0 C to a 70 C Typ 125 100 220 95 Max ns ns ns ns ns ns ns ns Units Note 3 Except for special case restriction with interrupts programmed max read strobe width of control register (ADDR 0) is 30 ms See section on Interrupt Programming Note 4 All timings measured to the trailing edge of write strobe (data latched by the trailing edge of WR) Note 5 Input test waveform peak voltages are 2 4V and 0 4V Output signals are measured to their 2 4V and 0 4V levels Note 6 Write stobe as used in the Write Timing Table is defined as the period when both chip select and write inputs are low ie WS e CS a WR Hence write strobe commences when both signals are low and terminates when the first signal returns high Note 7 Read strobe as used in the Read Timing Table is defined as the period when both chip select and read inputs are low ie RS e CS a RD Note 8 Typical numbers are at VCC e 5 0V and TA e 25 C 3 Switching Time Waveforms Read Cycle Timing (Notes 5 and 7) TL F 11011 – 3 Write Cycle Timing (Notes 5 and 6) TL F 11011 – 4 FIGURE 2 Functional Description The NS32FX211 is a bus oriented microprocessor real time clock Crystal Oscillator This consists of a CMOS inverter amplifier with an on-chip bias resistor Externally a 22 pF capacitor a 6 pF– 40 pF trimmer capacitor and a crystal are suggested to complete the 32 768 kHz timekeeping oscillator circuit The 6 pF – 40 pF trimmer fine tunes the crystal load impedance optimizing the oscillator stability When properly adjusted (i e to the crystal frequency of 32 768 kHz) the circuit will display a frequency variation with voltage of less than 3 ppm V When an external oscillator is used connect to oscillator input and float (no connection) the oscillator output When the chip is enabled into test mode the oscillator is gated onto the interrupt output pin giving a buffered oscillator output that can be used to set the crystal frequency when the device is installed in a system Divider Chain The crystal oscillator is divided down in three stages to produce a 10 Hz frequency setting pulse The first stage is a non-integer divider which reduces the 32 768 kHz input to 20 720 kHz This is further divided by a 9-stage binary ripple counter giving an output frequency of 60 Hz A 3-stage 4 Johnson counter divides this by six generating a 10 Hz output The 10 Hz clock is gated with the 32 768 kHz crystal frequency to provide clock setting pulses of 15 26 ms duration The setting pulse drives all the time registers on the device which are synchronously clocked by this signal All time data and data-changed flag change on the falling edge of the clock setting pulse Data-Changed Flag The data-changed flag is set by the clock setting pulse to indicate that the time data has been altered since the clock was last read This flag occupies bit 3 of the control register where it can be tested by the processor to sense datachanged It will be reset by a read of the control register See the section ‘‘Methods of Device Operation’’ for suggested clock reading techniques using this flag Seconds Counters There are three counters for seconds a tenths of seconds b units of seconds c tens of seconds The registers are accessed at the addresses shown in Table I The tenths of seconds register is reset to 0 when the clock start stop bit (bit 2 of the control register) is set to Functional Description (Continued) RCH only used for recharageable batteries TL F 11011 – 5 FIGURE 3 Typical System Connection Diagram logic 1 The units and tens of seconds are set up by the processor giving time setting to the nearest second All three registers can be read by the processor for time output Minutes Counters There are two minutes counters a units of minutes b tens of minutes Both registers may be read to or written from as required Hours Counters There are two hours counters a units of hours b tens of hours Both counters may be accessed for read or write operations as desired In 12-hour mode the tens of hours register has only one active bit and the top three bits are set to logic 0 Data bit 1 of the clock setting register is the AM PM indicator logic 0 indicating AM logic 1 for PM When 24-hour mode is programmed the tens of hours register reads out two bits of data and the two most significant bits are set to logic 0 There is no AM PM indication and bit 1 of the clock setting register will read out a logic 0 In both 12 24-hour modes the units of hours will read out four active data bits 12 or 24-hour mode is selected by bit 0 of the clock setting register logic 0 for 12-hour mode logic 1 for the 24-hour mode Days Counters There are two days counters a units of day b tens of days The days counters will count up to 28 29 30 or 31 depending on the state of the months counters and the leap year counter The microprocessor has full read write access to these registers Months Counters There are two months counters a units of months b tens of months Both these counters have full read write access Years Counters There are two years counters a units of years b tens of years Both these counters have full read write access The years will count up to 99 and roll over to 00 5 Functional Description (Continued) TABLE I Address Decoding of Real-Time Clock Internal Registers Registered Select AD3 0 Control Register 1 Tenths of Seconds 2 Units Seconds 3 Tens Seconds 4 Units Minutes 5 Tens Minutes 6 Unit Hours 7 Tens Hours 8 Units Days 9 Tens Days 10 Units Months 11 Tens Months 12 Units Years 13 Tens Years 14 Days of Week 15 Clock Setting Interrupt Registers 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 Address (Binary) AD2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 AD1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 AD0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 2 3 4 5 6 7 8 9 A B C D E F Split Read and Write Read Only RW RW RW RW RW RW RW RW RW RW RW RW RW RW (Hex) Access Day of Week Counter The day of week counter increments as the time rolls from 23 59 to 00 00 (11 59 PM to 12 00 AM in 12-hour mode) It counts from 1 to 7 and rolls back to 1 Any day of the week may be specified as day 1 Clock Setting Register Interrupt Register The interrupt select bit in the control register determines which of these two registers is accessible to the processor at address 15 Normal clock and interrupt timing operations will always continue regardless of which register is selected onto the bus The layout of these registers is shown in Table II The clock setting register is comprised of three separate functions a leap year counter bits 2 and 3 b AM PM indicator bit 1 c 12 24-hour mode set bit 0 (see Table IIA) The leap year counter is a 2-stage binary counter which is clocked by the months counter It changes state as the time rolls over from 11 59 on December 31 to 00 00 on January 1 The counter should be loaded with the ‘number of years since last leap year’ e g if 1980 was the last leap year a clock programmed in 1983 should have 3 stored in the leap year counter If the clock is programmed during a leap year then the leap year counter should be set to 0 The contents of the leap year counter can be read by the mP The AM PM indicator returns a logic 0 for AM and a logic 1 for PM It is clocked when the hours counter rolls from 11 59 to 12 00 in 12-hour mode In 24-hour mode this bit is set to logic 0 The 12 24-hour mode set determines whether the hours counter counts from 1 to 12 or from 0 to 23 It also controls the AM PM indicator enabling it for 12-hour mode and forcing it to logic 0 for the 24-hour mode The 12 24-hour mode bit is set to logic 0 for 12-hour mode and it is set to logic 1 for 24-hour mode IMPORTANT NOTE Hours mode and AM PM bits cannot be set in the same write operation See the section on Initialization (Methods of Device Operation) for a suggested setting routine All bits in the clock setting register may be read by the processor The interrupt register controls the operation of the timer for interrupt output The processor programs this register for single or repeated interrupts at the selected time intervals The lower three bits of this register set the time delay period that will occur between interrupts The time delays that can be programmed and the data words that select these are outlined in Table IIB Data bit 3 of the interrupt register sets for either single or repeated interrupts logic 0 gives single mode logic 1 sets for repeated mode Using the interrupt is described in the Device Operation section 6 Functional Description (Continued) TABLE IIA Clock Setting Register Layout Function DB3 Leap Year Counter AM PM Indicator (12-Hour Mode) 12 24-Hour Select Bit X Data Bits Used DB2 X X X DB1 DB0 0 Indicates a Leap Year 0 e AM 1 e PM 0 in 24-Hour Mode 0 e 12-Hour Mode 1 e 24-Hour Mode RW RW RW Comments Access TABLE IIB Interrupt Control Register Function No Interrupt 0 1 Second 0 5 Second 1 Second 5 Seconds 10 Seconds 30 Seconds 60 Seconds Comments DB3 Interrupt Output Cleared Start Stop Bit Set to 1 X 0 0 0 0 0 0 0 1 1 1 1 1 1 1 0 0 0 0 1 1 1 1 Control Word DB2 DB1 0 0 1 1 0 0 1 1 DB0 0 1 0 1 0 1 0 1 DB3 e 0 for Single Interrupt DB3 e 1 for Repeated Interrupt Timing Accuracy Single Interrupt Mode (all time delays) g 1 ms Repeated Mode g 1 ms on Initial Timeout Thereafter Synchronous with First Interrupt (i e timing errors do not accumulate) Control Register There are three registers which control different operations of the clock a the clock setting register b the interrupt register c the control register The clock setting and interrupt registers both reside at address 15 access to one or the other being controlled by the interrupt select bit data bit 1 of the control register The clock setting register programs the timekeeping of the clock The 12 24-hour mode select and the AM PM indicator for 12-hour mode occupy bits 0 and 1 respectively Data bits 2 and 3 set the leap year counter The interrupt register controls the operation of the interrupt timer selecting the required delay period and either single or repeated interrupt The control register is responsible for controlling the operations of the clock and supplying status information to the processor It appears as two different registers one with write only access and one with read only access The write only register consists of a bank of four latches which control the internal processes of the clock The read only register contains two output data latches which will supply status information for the processor Table III shows the mapping of the various control latches and status flags in the control register The control register is located at address 0 The write only portion of the control register contains four latches A logic 1 written into the test bit puts the device into test mode This allows setting of the oscillator frequency For normal operation the test bit is loaded with logic 0 The clock start stop bit stops the timekeeping of the clock and resets to 0 the tenths of seconds counter The time of day may then be written into the various clock registers and the clock restarted synchronously with an external time source Timekeeping is maintained thereafter A logic 1 written to the start stop bit halts clock timing Timing is restarted when the start stop bit is written with a logic 0 The interrupt select bit determines which of the two registers mapped onto address 15 will be accessed when this address is selected A logic 0 in the interrupt select bit makes the clock setting register available to the processor A logic 1 selects the interrupt register The interrupt start stop bit controls the running of the interrupt timer It is programmed in the same way as the clock start stop bit logic 1 to halt the interrupt and reset the timer logic 0 to start interrupt timing When no interrupt is programmed (interrupt control register set to 0) the interrupt start stop bit is automatically set to a logic 1 When any new interrupt is subsequently programmed timing will not commence until the start stop bit is loaded with 0 In the single interrupt mode interrupt timing stops when a timeout occurs The processor restarts timing by writing logic 0 into the start stop bit In repeated interrupt mode the interrupt timer continues to count with no intervention by the processor necessary 7 Functional Description (Continued) TABLE III The Control Register Layout Access (addr0) Read From Write To DB3 Data-Changed Flag Test 0 e Normal 1 e Test Mode DB2 0 Clock Start Stop 0 e Clock Run 1 e Clock Stop DB1 0 Interrupt Select 0 e Clock Setting Register 1 e Interrupt Register DB0 Interrupt Flag Interrupt Start Stop 0 e Interrupt Run 1 e Interrupt Stop Interrupt timing may be stopped in either mode by writing a logic 1 into the interrupt start stop bit The timer is reset and can be restarted in the normal way giving a full time delay period before the next interrupt In general the control register is set up such that writing 0’s into it will start anything that is stopped pull the clock out of test mode and select the clock setting register onto the bus In other words writing 0 will maintain normal clock operation and restart interrupt timing etc The read only portion of the control register has two status outputs Since the NS32FX211 keeps real time the time data changes asynchronously with the processor and this may occur while the processor is reading time data out of the clock Some method of warning the processor when the time data has changed must thus be included This is provided for by the data-changed flag located in bit 3 of the control register This flag is set by the clock setting pulse which also clocks the time registers Testing this bit can tell the processor whether or not the time has changed The flag is cleared by a read of the control register but not by any write operations No other register read has any effect on the state of the data-changed flag Data bit 0 is the interrupt flag This flag is set whenever the interrupt timer times out pulling the interrupt output low In a polled interrupt routine the processor can test this flag to determine if the NS32FX211 was the interrupting device This interrupt flag and the interrupt output are both cleared by a read of the control register Both of the flags and the interrupt output are reset by the trailing edge of the read strobe The flag information is held latched during a control register read guaranteeing that stable status information will always be read out by the processor Interrupt timeout is detected and stored internally if it occurs during a read of the control register the interrupt output will then go low only after the read has been completed A clock setting pulse occurring during a control register read will not affect the data-changed flag since time data read out before or after the control read will not be affected by the time change Initialization When it is first installed and power is applied the NS32FX211 will need to be properly initialized The following operation steps are recommended when the device is set up (all numbers are decimal) 1) Disable interrupt on the processor to allow oscillator setting Write 1510 into the control register The clock and interrupt start stop bits are set to 1 ensuring that the clock and interrupt timers are both halted Test mode and the interrupt register are selected 2) Write 0 to the interrupt register Ensure that there are no interrupts programmed and that the oscillator will be gated onto the interrupt output 3) Set oscillator frequency All timing has been halted and the oscillator is buffered out onto the interrupt line 4) Write 5 to the control register The clock is now out of test mode but is still halted The clock setting register is now selected by the interrupt select bit 5) Write 0001 to all registers This ensures starting with a valid BCD value in each register 6) Set 12 24 Hours Mode Write to the clock setting register to select the hours counting mode required 7) Load Real-Time Registers All time registers (including Leap Years and AM PM bit) may now be loaded in any order Note that when writing to the clock setting register to set up Leap Years and AM PM the Hours Mode bit must not be altered from the value programmed in step 5 8) Write 0 to the control register This operation finishes the clock initialization by starting the time The final control register write should be synchronized with an external time source In general timekeeping should be halted before the time data is altered in the clock The data can however be altered at any time if so desired Such may be the case if the user wishes to keep the clock corrected without having to stop and restart it i e winter summer time changing can be accomplished without halting the clock This can be done in software by sensing the state of the data-changed flag and only altering time data just after the time has rolled over (data-changed flag set) Reading the Time Registers Using the data-changed flag technique supports microprocessors with block move facilities as all the necessary time data may be read sequentially and then tested for validity as shown below 1) Read the control register address 0 This is a dummy read to reset the data-changed flag (DCF) prior to reading the time registers 2) Read time registers All desired time registers are read out in a block 3) Read the control register and test DCF If DCF is cleared (logic 0) then no clock setting pulses have after occurred since step 1 All time data is guaranteed good and time reading is complete If DCF is set (logic 1) then a time change has occurred since step 1 and time data may not be consistent Repeat steps 2 and 3 until DCF is clear The control read of step 3 will have reset DCF automatically repeating the step 1 action 8 Functional Description (Continued) Interrupt Programming The interrupt timer generates interrupts at time intervals which are programmed into the interrupt register A single interrupt after delay or repeated interrupts may be programmed Table IIB lists the different time delays and the data words that select them in the interrupt register Once the interrupt register has been used to set up the delay time and to select for single or repeat it takes no further part in the workings of the interrupt system All activity by the processor then takes place in the control register Initializing 1) Write 3 to the control register (AD0) Clock timing continues interrupt register selected and interrupt timing stopped 2) Write interrupt control word to address 15 The interrupt register is loaded with the correct word (chosen from Table IIB) for the time delay required and for single or repeated interrupts 3) Write 0 or 2 to the control register Interrupt timing commences Writing 0 selects the clock setting register onto the data bus writing 2 leaves the interrupt register selected Normal timekeeping remains unaffected On Interrupt Read the control register and test for Interrupt Flag (bit 0) If the flag is cleared (logic 0) then the device is not the source of the interrupt If the flag is set (logic 1) then the clock did generate an interrupt The flag is reset and the interrupt output is cleared by the control register read that was used to test for interrupt Single Interrupt Mode When appropriate write 0 or 2 to the control register to restart the interrupt timer Repeated Interrupt Mode Timing continues synchronized with the control register write which originally started interrupt timing No further intervention is necessary from the processor to maintain timing In either mode interrupt timing can be stopped by writing 1 into the control register (interrupt start stop set to 1) Timing for the full delay period recommences when the interrupt start stop bit is again loaded with 0 as normal IMPORTANT NOTE Using the interrupt timer places a constraint on the maximum Read Strobe width which may be applied to the clock Normally all registers may be read from with a tRW down to DC (i e CS and RD held continuously low) When the interrupt timer is active however the maximum read strobe width that can be applied to the control register (Addr 0) is 30 ms This restriction is to allow the interrupt timer to properly reset when it times out Note that it only affects reading of the control register all other addresses in the clock may be accessed with DC read strobes regardless of the state of the interrupt timer Writes to any address are unaffected APPLICATION HINTS Time Reading Using Interrupt In systems such as point of sale terminals and data loggers time reading is usually only required on a random demand basis Using the data-changed flag as outlined in the section on methods of operation is ideal for this type of system Some systems however need to sense a change in real time e g industrial timers process controllers TV VCR clocks any system where real time is displayed The interrupt timer on the NS32FX211 can generate interrupts synchronously with the time registers changing using software to provide the initial synchronization In single interrupt mode the processor is responsible for initiating each timing cycle and the timed period is accurate to g 1 ms In repeated interrupt mode the period from the initial processor start to the first timeout is also only accurate to g 1 ms The following interrupts maintain accurate delay periods relative to the first timeout Thus to utilize interrupt to control time reading we will use repeated interrupt mode In repeated mode the time period between interrupts is exact which means that timeouts will always occur at the same point relative to the internal clock setting pulses The case for 0 1s interrupts is shown in Figure A-1 The same is true for other delay periods only there will be more clock setting pulses between each interrupt timeout If we set up the interrupt timer so that interrupt always times out just after the clock setting pulse occurs (Figure A-2) then there is no need to test the data-changed flag as we know that the time data has just changed and will not alter again for another 100 ms This can be achieved as outlined below 1) Follow steps 1 and 2 of the section on interrupt programming In step 2 set up for repeated interrupt 2) Read control register AD0 This is a dummy read to reset the data-changed flag 3) Read control register AD0 until data-changed flag is set 4) Write 0 or 2 to control register Interrupt timing commences Time Reading with Very Slow Read Cycles If a system takes longer than 100 ms to complete reading of all the necessary time registers (e g when CMOS processors are used) or where high level interpreted language routines are used then the data-changed flag will always be set when tested and is of no value In this case the time registers themselves must be tested to ensure data accuracy The technique below will detect both time changing between read strobes (i e between reading tens of minutes and units of hours) and also time changing during read which can produce invalid data 1) Read and store the value of the lowest order time register required 9 Functional Description (Continued) 2) Read out all the time registers required The registers may be read out in any order simplifying software requirements 3) Read the lowest order register and compare it with the value stored previously in step 1 If it is still the same then all time data is good If it has changed then store the new value and go back to step 2 In general the rule is that the first and last reads must both be of the lowest order time register These two values can then be compared to ensure that no change has occurred This technique works because for any higher order time register to change all the lower order registers must also change If the lowest order register does not change then no higher order register has changed either TL F 11011 – 6 FIGURE A-1 Time Delay from Clock Setting Pulses to Interrupt is Constant TL F 11011 – 7 FIGURE A-2 Interrupt Timer Synchronized with Clock Setting Pulses 10 Physical Dimensions inches (millimeters) Cavity Dual-In-Line Package (J) Order Number NS32FX211J NS Package Number J16A Molded Dual-In-Line Package (N) Order Number NS32FX211N NS Package Number N16A 11 NS32FX211 Microprocessor Compatible Real Time Clock Physical Dimensions inches (millimeters) (Continued) Plastic Chip Carrier (V) Order Number NS32FX211V NS Package Number V20A LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL SEMICONDUCTOR CORPORATION As used herein 1 Life support devices or systems are devices or systems which (a) are intended for surgical implant into the body or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user National Semiconductor Corporation 1111 West Bardin Road Arlington TX 76017 Tel 1(800) 272-9959 Fax 1(800) 737-7018 2 A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness National Semiconductor Europe Fax (a49) 0-180-530 85 86 Email cnjwge tevm2 nsc com Deutsch Tel (a49) 0-180-530 85 85 English Tel (a49) 0-180-532 78 32 Fran ais Tel (a49) 0-180-532 93 58 Italiano Tel (a49) 0-180-534 16 80 National Semiconductor Hong Kong Ltd 13th Floor Straight Block Ocean Centre 5 Canton Rd Tsimshatsui Kowloon Hong Kong Tel (852) 2737-1600 Fax (852) 2736-9960 National Semiconductor Japan Ltd Tel 81-043-299-2309 Fax 81-043-299-2408 National does not assume any responsibility for use of any circuitry described no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications