X1286 ® 2-Wire™ RTC, 256k (32k x 8) Data Sheet April 14, 2006 Intersil Real Time Clock/Calendar/CPU Supervisor with EEPROM FEATURES • Real Time Clock/Calendar — Tracks time in Hours, Minutes, Seconds and Hundredths of a Second — Day of the Week, Day, Month, and Year • 2 Polled Alarms (Non-volatile) — Settable on the Second, Minute, Hour, Day of the Week, Day, or Month — Repeat Mode (periodic interrupts) • Oscillator Compensation on chip — Internal feedback resistor and compensation capacitors — 64 position Digitally Controlled Trim Capacitor — 6 digital frequency adjustment settings to ±30ppm • Battery Switch or Super Cap Input • 32K x 8 Bits of EEPROM — 128-Byte Page Write Mode — 8 modes of Block Lock™ Protection — Single Byte Write Capability • High Reliability — Data Retention: 100 years — Endurance: 100,000 cycles per byte • 2-Wire™ Interface interoperable with I2C* — 400kHz data transfer rate FN8101.1 • Frequency Output (SW Selectable: Off, 1Hz, 100Hz, or 32.768kHz) • Low Power CMOS — 1.25µA Operating Current (Typical) • Small Package Options — 8 Ld EIAJ SOIC and 14 Ld TSSOP • Repetitive Alarms • Temperature Compensation APPLICATIONS • • • • • • • • • • • • • • • Utility Meters HVAC Equipment Audio/Video Components Set Top Box/Television Modems Network Routers, Hubs, Switches, Bridges Cellular Infrastructure Equipment Fixed Broadband Wireless Equipment Pagers/PDA POS Equipment Test Meters/Fixtures Office Automation (Copiers, Fax) Home Appliances Computer Products Other Industrial/Medical/Automotive BLOCK DIAGRAM OSC Compensation X1 32.768kHz Oscillator X2 SCL SDA 1Hz Timer Calendar Logic Time Keeping Registers (SRAM) Battery Switch Circuitry VCC VBACK Select Serial Interface Decoder Control Decode Logic Control/ Registers (EEPROM) Status Registers Compare Alarm (SRAM) Mask PHZ/IRQ Frequency Divider 8 Alarm Regs (EEPROM) 256K EEPROM ARRAY 1 CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright Intersil Americas Inc. 2005, 2006. All Rights Reserved All other trademarks mentioned are the property of their respective owners. X1286 PIN DESCRIPTIONS 8 LD EIAJ SOIC 14 LD TSSOP X1 1 8 VCC X1 1 14 VCC X2 2 7 VBACK X2 2 13 VBACK PHZ/IRQ 3 6 SCL NC 3 12 NC VSS 4 5 SDA NC 4 11 NC NC 5 10 NC PHZ/IRQ 6 9 SCL 8 SDA VSS 7 Ordering Information PART NUMBER PART MARKING VCC RANGE (V) TEMP. RANGE (°C) PACKAGE 2.7 to 5.5 0 to 70 8 Ld EIAJ SOIC 8 Ld EIAJ SOIC PKG. DWG. # X1286A8* X1286A X1286A8I* X1286A I -40 to 85 X1286V14* X1286 V 0 to 70 14 Ld TSSOP (4.4mm) MDP0044 X1286V14Z* (Note) X1286 VZ 0 to 70 14 Ld TSSOP (4.4mm) (Pb-free) MDP0044 X1286V14I* X1286 VI -40 to 85 14 Ld TSSOP (4.4mm) MDP0044 X1286V14IZ* (Note) X1286 VIZ -40 to 85 14 Ld TSSOP (4.4mm) (Pb-free) MDP0044 *Add "T1" suffix for tape and reel. NOTE: Intersil Pb-free plus anneal products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin plate termination finish, which are RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. 2 FN8101.1 April 14, 2006 X1286 PIN ASSIGNMENTS Pin Number EIAJ SOIC TSSOP Symbol Brief Description 1 1 X1 X1. The X1 pin is the input of an inverting amplifier. An external 32.768kHz quartz crystal is used with the X1286 to supply a timebase for the real time clock. The recommended crystal is a Citizen CFS206-32.768KDZF. Internal compensation circuitry is included to form a complete oscillator circuit. Care should be taken in the placement of the crystal and the layout of the circuit. Plenty of ground plane around the device and short traces to X1 are highly recommended. See Application section for more recommendations. 2 2 X2 X2. The X2 pin is the output of an inverting amplifier. An external 32.768kHz quartz crystal is used with the X1286 to supply a timebase for the real time clock. The recommended crystal is a Citizen CFS206-32.768KDZF. Internal compensation circuitry is included to form a complete oscillator circuit. Care should be taken in the placement of the crystal and the layout of the circuit. Plenty of ground plane around the device and short traces to X2 are highly recommended. See Application section for more recommendations. 3 6 PHZ/IRQ Programmable Frequency/Interrupt Output – PHZ/IRQ. This is either an output from the internal oscillator or an interrupt signal output. It is a CMOS output. When used as frequency output, this signal has a frequency of 32.768kHz, 100Hz, 1Hz or inactive. When used as interrupt output, this signal notifies a host processor that an alarm has occurred and an action is required. It is an active LOW output. The control bits for this function are FO1 and FO0 and are found in address 0011h of the Clock Control Memory map. See “Programmable Frequency Output Bits—FO1, FO0” on page 13. 4 7 VSS VSS. 5 8 SDA Serial Data (SDA). SDA is a bidirectional pin used to transfer data into and out of the device. It has an open drain output and may be wire ORed with other open drain or open collector outputs. The input buffer is always active (not gated). An open drain output requires the use of a pull-up resistor. The output circuitry controls the fall time of the output signal with the use of a slope controlled pulldown. The circuit is designed for 400kHz 2-wire interface speed. 6 9 SCL Serial Clock (SCL). The SCL input is used to clock all data into and out of the device. The input buffer on this pin is always active (not gated). 7 13 VBACK VBACK. This input provides a backup supply voltage to the device. VBACK supplies power to the device in the event the VCC supply fails. This pin can be connected to a battery, a Supercap or tied to ground if not used. 8 14 VCC 3 VCC. FN8101.1 April 14, 2006 X1286 ABSOLUTE MAXIMUM RATINGS Temperature Under Bias ................... -65°C to +135°C Storage Temperature......................... -65°C to +150°C Voltage on VCC, VBACK and PHZ/IRQ pin (respect to ground) ............................-0.5V to 7.0V Voltage on SCL, SDA, X1 and X2 pin (respect to ground) ............... -0.5V to 7.0V or 0.5V above VCC or VBACK (whichever is higher) DC Output Current .............................................. 5 mA Lead Temperature (Soldering, 10s) ................... 300°C Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and the functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. DC OPERATING CHARACTERISTICS (Temperature = -40°C to +85°C, unless otherwise stated.) Symbol VCC VBACK Max Unit Main Power Supply Parameter 2.7 5.5 V Backup Power Supply 1.8 5.5 V VBACK -0.2 VBACK -0.1 V VBACK VBACK +0.2 V Max Unit Notes µA 1, 5, 7, 14 VCB Switch to Backup Supply VBC Switch to Main Supply Conditions Min Typ Notes OPERATING CHARACTERISTICS Symbol Parameter Conditions ICC1 Read Active Supply Current VCC = 2.7V 400 VCC = 5.0V 800 µA ICC2 Program Supply Current (nonvolatile) VCC = 2.7V 2.5 mA VCC = 5.0V 3.0 mA VCC = 2.7V 10 µA 20 µA ICC3 Main Timekeeping Current IBACK Timekeeping Current Min Typ VCC = 5.0V 2, 5, 7, 14 3, 7, 8, 14, 15 VBACK = 1.8V 1.25 µA 3, 6, 9, 14, 15 VBACK = 3.3V 1.5 µA “See Performance Data” ILI Input Leakage Current 10 µA 10 ILO Output Leakage Current 10 µA 10 VIL Input LOW Voltage -0.5 VCC x 0.2 or VBACK x 0.2 V 13 VIH Input HIGH Voltage VCC x 0.7 or VBACK x 0.7 VCC + 0.5 or VBACK + 0.5 V 13 V 13 V 11 V 11 V 12 VHYS Schmitt Trigger Input Hysteresis VOL1 Output LOW Voltage for SDA VOL2 Output LOW Voltage for PHZ/IRQ VOH2 Output HIGH Voltage for PHZ/IRQ 4 VCC related level .05 x VCC or .05 x VBACK VCC = 2.7V 0.4 VCC = 5.5V 0.4 VCC = 2.7V VCC x 0.3 VCC = 5.5V VCC x 0.3 VCC = 2.7V VCC x 0.7 VCC = 5.5V VCC x 0.7 FN8101.1 April 14, 2006 X1286 Notes: (1) The device enters the Active state after any start, and remains active: for 9 clock cycles if the Device Select Bits in the Slave Address Byte are incorrect or until 200nS after a stop ending a read or write operation. (2) The device enters the Program state 200nS after a stop ending a write operation and continues for tWC. (3) The device goes into the Timekeeping state 200nS after any stop, except those that initiate a nonvolatile write cycle; tWC after a stop that initiates a nonvolatile write cycle; or 9 clock cycles after any start that is not followed by the correct Device Select Bits in the Slave Address Byte. (4) For reference only and not tested. (5) VIL = VCC x 0.1, VIH = VCC x 0.9, fSCL = 400KHz (6) VCC = 0V (7) VBACK = 0V (8) VSDA = VSCL=VCC, Others = GND or VCC (9) VSDA =VSCL=VBACK, Others = GND or VBACK (10)VSDA = GND or VCC, VSCL = GND or VCC, VRESET = GND or VCC (11) IOL = 3.0mA at 5.5V, 1.5mA at 2.7V (12) IOH = -1.0mA at 5.5V, -0.4mA at 2.7V (13)Threshold voltages based on the higher of Vcc or Vback. (14)Using recommended crystal and oscillator network applied to X1 and X2 (25°C). (15)Typical values are for TA = 25°C Capacitance TA = 25°C, f = 1.0 MHz, VCC = 5V Symbol COUT (1) CIN(1) Parameter Max. Units Test Conditions Output Capacitance (SDA, PHZ/IRQ) 10 pF VOUT = 0V Input Capacitance (SCL) 10 pF VIN = 0V Notes: (1) This parameter is not 100% tested. (2) The input capacitance between x1 and x2 pins can be varied between 5pF and 19.75pF by using analog trimming registers AC CHARACTERISTICS AC Test Conditions Input Pulse Levels VCC x 0.1 to VCC x 0.9 Input Rise and Fall Times 10ns Input and Output Timing Levels VCC x 0.5 Output Load Standard Output Load Figure 1. Standard Output Load for testing the device with VCC = 5.0V Equivalent AC Output Load Circuit for VCC = 5V 5.0V 5.0V 1533Ω For VOL= 0.4V 1316Ω and IOL = 3 mA PHZ/IRQ SDA 100pF 5 806Ω 100pF FN8101.1 April 14, 2006 X1286 AC Specifications (TA = -40°C to +85°C, VCC = +2.7V to +5.5V, unless otherwise specified.) Symbol Parameter Min. tIN Pulse width Suppression Time at inputs 50(1) tAA SCL LOW to SDA Data Out Valid tBUF Time the bus must be free before a new transmission can start 1.3 µs tLOW Clock LOW Time 1.3 µs tHIGH Clock HIGH Time 0.6 µs tSU:STA Start Condition Setup Time 0.6 µs tHD:STA Start Condition Hold Time 0.6 µs fSCL SCL Clock Frequency Max. Units 400 kHz ns 0.9 µs tSU:DAT Data In Setup Time 100 ns tHD:DAT Data In Hold Time 0 µs tSU:STO Stop Condition Setup Time 0.6 µs Data Output Hold Time 50 ns tDH tR SDA and SCL Rise Time tF SDA and SCL Fall Time Cb Capacitive load for each bus line 20 +.1Cb(1)(2) 300 ns 20 +.1Cb(1)(2) 300 ns 400 pF Notes: (1) This parameter is not 100% tested. (2) Cb = total capacitance of one bus line in pF. TIMING DIAGRAMS Bus Timing tHIGH tF SCL tLOW tR tSU:DAT tSU:STA SDA IN tHD:STA tHD:DAT tSU:STO tAA tDH tBUF SDA OUT 6 FN8101.1 April 14, 2006 X1286 Write Cycle Timing SCL SDA 8th Bit of Last Byte ACK tWC Stop Condition Start Condition Power-up Timing Symbol tPUR (1) (1) tPUW Parameter Min. Typ.(2) Max. Units Time from Power-up to Read 1 ms Time from Power-uppower-up to Write 5 ms Notes: (1) Delays are measured from the time VCC is stable until the specified operation can be initiated. These parameters are not 100% tested. VCC slew rate should be between 0.2mV/µsec and 50mV/µsec. (2) Typical values are for TA = 25°C and VCC = 5.0V Nonvolatile Write Cycle Timing Symbol tWC Note: (1) Parameter Write Cycle Time Min. Typ.(1) Max. Units 5 10 ms (1) tWC is the time from a valid stop condition at the end of a write sequence to the end of the self-timed internal nonvolatile write cycle. It is the minimum cycle time to be allowed for any nonvolatile write by the user, unless Acknowledge Polling is used. 7 FN8101.1 April 14, 2006 X1286 DESCRIPTION Serial Clock (SCL) The X1286 device is a Real Time Clock with clock/calendar, two polled alarms with integrated 32kx8 EEPROM, oscillator compensation, and battery backup switch. The SCL input is used to clock all data into and out of the device. The input buffer on this pin is always active (not gated). The oscillator uses an external, low-cost 32.768kHz crystal. All compensation and trim components are integrated on the chip. This eliminates several external discrete components and a trim capacitor, saving board area and component cost. Serial Data (SDA) The Real-Time Clock keeps track of time with separate registers for Hours, Minutes, Seconds and 1/100 of a second. The Calendar has separate registers for Date, Month, Year and Day-of-week. The calendar is correct through 2099, with automatic leap year correction. The powerful Dual Alarms can be set to any Clock/Calendar value for a match. For instance, every minute, every Tuesday, or 5:23 AM on March 21. The alarms can be polled in the Status Register or provide a hardware interrupt (IRQ Pin). There is a repeat mode for the alarms allowing a periodic interrupt. SDA is a bidirectional pin used to transfer data into and out of the device. It has an open drain output and may be wire ORed with other open drain or open collector outputs. The input buffer is always active (not gated). An open drain output requires the use of a pull-up resistor. The output circuitry controls the fall time of the output signal with the use of a slope controlled pulldown. The circuit is designed for 400kHz 2-wire interface speed. VBACK This input provides a backup supply voltage to the device. VBACK supplies power to the device in the event the VCC supply fails. This pin can be connected to a battery, a Supercap or tied to ground if not used. The PHZ/IRQ pin may be software selected to provide a frequency output of 1 Hz, 100 Hz, or 32,768 Hz. Programmable Frequency/Interrupt Output – PHZ/IRQ The device offers a backup power input pin. This VBACK pin allows the device to be backed up by battery or SuperCap. The entire X1286 device is fully operational from 2.7 to 5.5 volts and the clock/calendar portion of the X1286 device remains fully operational down to 1.8 volts (Standby Mode). When used as frequency output, this signal has a frequency of 32.768kHz, 100Hz, 1Hz or inactive. The X1286 device provides 256K bits of EEPROM with 8 modes of BlockLock™ control. The BlockLock allows a safe, secure memory for critical user and configuration data, while allowing a large user storage area. PIN DESCRIPTIONS 14- pin TSSOP 1 2 14 VCC 13 VBACK NC NC 3 12 NC 4 11 NC NC PHZ/IRQ 5 10 NC 6 9 SCL VSS 7 8 SDA X1 1 8 VCC X1 X2 2 7 VBACK X2 PHZ/IRQ 3 6 SCL 4 5 SDA 8 When used as interrupt output, this signal notifies a host processor that an alarm has occurred and an action is required. It is an active LOW output. The control bits for this function are FO1 and FO0 and are found in address 0011h of the Clock Control Memory map. See “Programmable Frequency Output Bits—FO1, FO0” on page 13. X1, X2 X1286 8-pin EIAJ SOIC VSS This is either an output from the internal oscillator or an interrupt signal output. It is a CMOS output. The X1 and X2 pins are the input and output, respectively, of an inverting amplifier. An external 32.768kHz quartz crystal is used with the X1286 to supply a timebase for the real time clock. The recommended crystal is a Citizen CFS206-32.768KDZF. Internal compensation circuitry is included to form a complete oscillator circuit. Care should be taken in the placement of the crystal and the layout of the circuit. Plenty of ground plane around the device and short traces to X1 and X2 are highly recommended. See Application section for more recommendations. FN8101.1 April 14, 2006 X1286 Figure 2. Recommended Crystal connection X1 X2 POWER CONTROL OPERATION The power control circuit accepts a VCC and a VBACK input. The power control circuit powers the clock from VBACK when VCC < VBACK - 0.2V. It will switch back to power the device from VCC when VCC exceeds VBACK. Figure 3. Power Control the end of a valid write sequence. An invalid write operation aborts the time update procedure and the contents of the buffer are discarded. After a valid write operation the RTC will reflect the newly loaded data beginning with the SSEC register reset to “0” at the next sub-second update after the stop bit is written. The 1Hz frequency output from the PHZ/IRQ pin will be reset to restart after the stop bit is written. The RTC continues to update the time while an RTC register write is in progress and the RTC continues to run during any nonvolatile write sequences. A single byte may be written to the RTC without affecting the other bytes. Accuracy of the Real Time Clock VCC Voltage VBACK On In Off REAL TIME CLOCK OPERATION The Real Time Clock (RTC) uses an external 32.768kHz quartz crystal to maintain an accurate internal representation of the 1/100 of a second, second, minute, hour, day, date, month, and year. The RTC has leap-year correction. The clock also corrects for months having fewer than 31 days and has a bit that controls 24 hour or AM/PM format. When the X1286 powers up after the loss of both VCC and VBACK, the clock will not operate until at least one byte is written to the clock register. Reading the Real Time Clock The RTC is read by initiating a Read command and specifying the address corresponding to the register of the Real Time Clock. The RTC Registers can then be read in a Sequential Read Mode. Since the clock runs continuously and a read takes a finite amount of time, there is the possibility that the clock could change during the course of a read operation. In this device, the time is latched by the read command (falling edge of the clock on the ACK bit prior to RTC data output) into a separate latch to avoid time changes during the read operation. The clock continues to run. Alarms occurring during a read are unaffected by the read operation. Writing to the Real Time Clock The time and date may be set by writing to the RTC registers. To avoid changing the current time by an uncompleted write operation, the current time value is loaded into a separate buffer at the falling edge of the clock on the ACK bit before the RTC data input bytes, the clock continues to run. The new serial input data replaces the values in the buffer. This new RTC value is loaded back into the RTC Register by a stop bit at 9 The accuracy of the Real Time Clock depends on the frequency of the quartz crystal that is used as the time base for the RTC. Since the resonant frequency of a crystal is temperature dependent, the RTC performance will also be dependent upon temperature. The frequency deviation of the crystal is a function of the turnover temperature of the crystal from the crystal’s nominal frequency. For example, a >20ppm frequency deviation translates into an accuracy of >1 minute per month. these parameters are available from the crystal manufacturer. Intersil’s RTC family provides on-chip crystal compensation networks to adjust loadcapacitance to tune oscillator frequency from +116 ppm to -37 ppm when using a 12.5 pF load crystal. For more detail information see the Application section. CLOCK/CONTROL REGISTERS (CCR) The Control/Clock Registers are located in an area separate from the EEPROM array and are only accessible following a slave byte of “1101111x” and reads or writes to addresses [0000h:003Fh]. The clock/control memory map has memory addresses from 0000h to 003Fh. The defined addresses are described in the Table 1. Writing to and reading from the undefined addresses are not recommended. CCR access The contents of the CCR can be modified by performing a byte or a page write operation directly to any address in the CCR. Prior to writing to the CCR (except the status register), however, the WEL and RWEL bits must be set using a two step process (See section “Writing to the Clock/Control Registers.”) The CCR is divided into 5 sections. These are: 1. 2. 3. 4. 5. Alarm 0 (8 bytes; non-volatile) Alarm 1 (8 bytes; non-volatile) Control (4 bytes; non-volatile) Real Time Clock (8 bytes; volatile) Status (1 byte; volatile) FN8101.1 April 14, 2006 X1286 Each register is read and written through buffers. The non-volatile portion (or the counter portion of the RTC) is updated only if RWEL is set and only after a valid write operation and stop bit. A sequential read or page write operation provides access to the contents of only one section of the CCR per operation. Access to another section requires a new operation. Continued reads or writes, once reaching the end of a section, will wrap around to the start of the section. A read or write can begin at any address in the CCR. buffer, so an update of the clock does not change the time being read. A sequential read of the CCR will not result in the output of data from the memory array. At the end of a read, the master supplies a stop condition to end the operation and free the bus. After a read of the CCR, the address remains at the previous address +1 so the user can execute a current address read of the CCR and continue reading the next Register. It is not necessary to set the RWEL bit prior to writing the status register. Section 5 supports a single byte read or write only. Continued reads or writes from this section terminates the operation. There are two alarm registers whose contents mimic the contents of the RTC register, but add enable bits and exclude the 24 hour time selection bit. The enable bits specify which registers to use in the comparison between the Alarm and Real Time Registers. For example: ALARM REGISTERS The state of the CCR can be read by performing a random read at any address in the CCR at any time. This returns the contents of that register location. Additional registers are read by performing a sequential read. The read instruction latches all Clock registers into a – Setting the Enable Month bit (EMOn*) bit in combination with other enable bits and a specific alarm time, the user can establish an alarm that triggers at the same time once a year. *n = 0 for Alarm 0: N = 1 for Alarm 1 Bit Addr. Type Reg Name 7 6 5 4 3 2 1 (optional) 003F Status SR BAT AL1 AL0 0 0 RWEL WEL RTCF 0037 RTC (SRAM) SSEC SS23 SS22 SS21 SS20 SS13 SS12 SS11 SS10 0-99 xxh DW 0 0 0 0 0 DY2 DY1 DY0 0-6 xxh 0035 YR Y23 Y22 Y21 Y20 Y13 Y12 Y11 Y10 0-99 xxh 0034 MO 0 0 0 G20 G13 G12 G11 G10 1-12 xxh 0036 0 Default Table 1. Clock/Control Memory Map Range 01h 0033 DT 0 0 D21 D20 D13 D12 D11 D10 1-31 xxh 0032 HR MIL 0 H21 H20 H13 H12 H11 H10 0-23 xxh 0031 MN 0 M22 M21 M20 M13 M12 M11 M10 0-59 xxh 0030 SC 0 S22 S21 S20 S13 S12 S11 S10 0-59 DTR 0 0 0 0 0 DTR2 DTR1 DTR0 ATR2 ATR1 ATR0 0013 0012 Control (EEPROM) 0011 0010 000F 000E Alarm1 (EEPROM) ATR 0 0 ATR5 ATR4 ATR3 INT IM AL1E AL0E FO1 FO0 Read Only Read Only Read Only BL BP2 BP1 BP0 WD1 WD0 Read Only Read Only Read Only Y2K1 DWA1 Read-only - Default = 20h EDW1 0 0 0 0 DY2 DY1 xxh 00h 00h 00h 00h 20 20h DY0 0-6 00h 00h 000D YRA1 000C MOA1 EMO1 Unused - Default = RTC Year value (No EEPROM) - Future expansion 0 0 A1G20 A1G13 A1G12 A1G11 A1G10 1-12 000B DTA1 EDT1 0 A1D21 A1D20 A1D13 A1D12 A1D11 A1D10 1-31 00h 000A HRA1 EHR1 0 A1H21 A1H20 A1H13 A1H12 A1H11 A1H10 0-23 00h 0009 MNA1 EMN1 A1M22 A1M21 A1M20 A1M13 A1M12 A1M11 A1M10 0-59 00h 0008 SCA1 ESC1 A1S22 A1S21 A1S20 A1S13 A1S12 A1S11 A1S10 0-59 00h 10 FN8101.1 April 14, 2006 X1286 Table 1. Clock/Control Memory Map (Continued) Addr. Type 0007 Alarm0 (EEPROM) 0006 0 7 6 5 Y2K0 DWA0 Default Bit Reg Name 4 2 1 (optional) Range 20 20h DY2 DY1 DY0 0-6 00h 00h 3 Read-only - Default = 20h EDW0 0 0 0 0 0005 YRA0 0004 MOA0 EMO0 Unused - Default = RTC Year value (No EEPROM) – Future expansion 0 0 A0G20 A0G13 A0G12 A0G11 A0G10 1-12 0003 DTA0 EDT0 0 A0D21 A0D20 A0D13 A0D12 A0D11 A0D10 1-31 00h 0002 HRA0 EHR0 0 A0H21 A0H20 A0H13 A0H12 A0H11 A0H10 0-23 00h 0001 MNA0 EMN0 A0M22 A0M21 A0M20 A0M13 A0M12 A0M11 A0M10 0-59 00h 0000 SCA0 ESC0 A0S22 A0S21 A0S20 A0S13 A0S12 A0S11 A0S10 0-59 00h When there is a match, an alarm flag is set. The occurrence of an alarm can be determined by polling the AL0 and AL1 bits or by enabling the IRQ output, using it as hardware flag. The alarm enable bits are located in the MSB of the particular register. When all enable bits are set to ‘0’, there are no alarms. – The user can set the X1286 to alarm every Wednesday at 8:00 AM by setting the EDWn*, the EHRn* and EMNn* enable bits to ‘1’ and setting the DWAn*, HRAn* and MNAn* Alarm registers to 8:00 AM Wednesday. – A daily alarm for 9:30PM results when the EHRn* and EMNn* enable bits are set to ‘1’ and the HRAn* and MNAn* registers are set to 9:30 PM. *n = 0 for Alarm 0: N = 1 for Alarm 1 REAL TIME CLOCK REGISTERS Clock/Calendar Registers (SSEC, SC, MN, HR, DT, MO, YR) These registers depict BCD representations of the time. As such, SSEC (1/100 Second) range from 00 to 99, SC (Seconds) and MN (Minutes) range from 00 to 59, HR (Hour) is 1 to 12 with an AM or PM indicator (H21 bit) or 0 to 23 (with MIL=1), DT (Date) is 1 to 31, MO (Month) is 1 to 12, YR (Year) is 0 to 99. The SSEC register is read-only. Date of the Week Register (DW) This register provides a Day of the Week status and uses three bits DY2 to DY0 to represent the seven days of the week. The counter advances in the cycle 0-1-2-3-4-5-6-0-1-2-… The assignment of a numerical value to a specific day of the week is arbitrary and may be decided by the system software designer. The default value is defined as ‘0’. 11 24 Hour Time If the MIL bit of the HR register is 1, the RTC uses a 24-hour format. If the MIL bit is 0, the RTC uses a 12hour format and H21 bit functions as an AM/PM indicator with a ‘1’ representing PM. The clock defaults to standard time with H21=0. Leap Years Leap years add the day February 29 and are defined as those years that are divisible by 4. Years divisible by 100 are not leap years, unless they are also divisible by 400. This means that the year 2000 is a leap year, the year 2100 is not. The X1286 does not correct for the leap year in the year 2100. STATUS REGISTER (SR) The Status Register is located in the CCR memory map at address 003Fh. This is a volatile register only and is used to control the WEL and RWEL write enable latches, read two power status and two alarm bits. This register is separate from both the array and the Clock/Control Registers (CCR). Table 2. Status Register (SR) Addr 7 6 5 4 3 2 1 0 003Fh BAT AL1 AL0 0 0 RWEL WEL RTCF Default 0 0 0 0 0 0 0 1 BAT: Battery Supply—Volatile This bit set to “1” indicates that the device is operating from VBACK, not VCC. It is a read-only bit and is set/reset by hardware (X1286 interally). Once the device begins operating from VCC, the device sets this bit to “0”. FN8101.1 April 14, 2006 X1286 AL1, AL0: Alarm bits—Volatile Unused Bits: These bits announce if either alarm 0 or alarm 1 match the real time clock. If there is a match, the respective bit is set to ‘1’. The falling edge of the last data bit in a SR Read operation resets the flags. Note: Only the AL bits that are set when an SR read starts will be reset. An alarm bit that is set by an alarm occurring during an SR read operation will remain set after the read operation is complete. This device does not use bits 3 or 4 in the SR, but must have a zero in these bit positions. The Data Byte output during a SR read will contain zeros in these bit locations. CONTROL REGISTERS The Control Bits and Registers, described under this section, are nonvolatile. RWEL: Register Write Enable Latch—Volatile RTCF: Real Time Clock Fail Bit—Volatile This bit is set to a “1” after a total power failure. This is a read only bit that is set by hardware (X1286 internally) when the device powers up after having lost all power to the device (both VCC and VBACK go to 0V). The bit is set regardless of whether VCC or VBACK is applied first. The loss of only one of the supplies does not set the RTCF bit to “1”. On power up after a total power failure, all registers are set to their default states and the clock will not increment until at least one byte is written to the clock register. The first valid write to the RTC section after a complete power failure resets the RTCF bit to “0” (writing one byte is sufficient). 12 Table 3. Block Protect Bits BP0 The WEL bit controls the access to the CCR and memory array during a write operation. This bit is a volatile latch that powers up in the LOW (disabled) state. While the WEL bit is LOW, writes to the CCR or any array address will be ignored (no acknowledge will be issued after the Data Byte). The WEL bit is set by writing a “1” to the WEL bit and zeroes to the other bits of the Status Register. Once set, WEL remains set until either reset to 0 (by writing a “0” to the WEL bit and zeroes to the other bits of the Status Register) or until the part powers up again. Writes to WEL bit do not cause a nonvolatile write cycle, so the device is ready for the next operation immediately after the stop condition. The Block Protect Bits, BP2, BP1 and BP0, determine which blocks of the array are write protected. A write to a protected block of memory is ignored. The block protect bits will prevent write operations to one of eight segments of the array. The partitions are described in Table 3 . BP1 WEL: Write Enable Latch—Volatile Block Protect Bits—BP2, BP1, BP0 BP2 This bit is a volatile latch that powers up in the LOW (disabled) state. The RWEL bit must be set to “1” prior to any writes to the Clock/Control Registers. Writes to RWEL bit do not cause a nonvolatile write cycle, so the device is ready for the next operation immediately after the stop condition. A write to the CCR requires both the RWEL and WEL bits to be set in a specific sequence. Protected Addresses X1286 Array Lock 0 0 0 None None (default) 0 0 1 6000h - 7FFFh Upper 1/4 0 1 0 4000h - 7FFFh Upper 1/2 0 1 1 0000h - 7FFFh Full Array 1 0 0 0000h - 007Fh First Page 1 0 1 0000h - 00FFh First 2 pgs 1 1 0 0000h - 01FFh First 4 pgs 1 1 1 0000h - 03FFh First 8 Pgs Watchdog Timer Control Bits—WD1, WD0 The bits WD1 and WD0 control the period of the Watchdog Timer. See Table 4 for options. Table 4. Watchdog Timer Time-Out Options WD1 WD0 Watchdog Time-Out Period 0 0 1.75 seconds (default) 0 1 750 milliseconds 1 0 250 milliseconds 1 1 Disabled FN8101.1 April 14, 2006 X1286 INTERRUPT CONTROL AND FREQUENCY OUTPUT REGISTER (INT) Interrupt Control and Status Bits (IM, AL1E, AL0E) There are two Interrupt Control bits, Alarm 1 Interrupt Enable (AL1E) and Alarm 0 Interrupt Enable (AL0E) to specifically enable or disable the alarm interrupt signal output (IRQ). The interrupts are enabled when either AL1E and AL0E are set to ‘1’, respectively. Two volatile bits (AL1 and AL0), associated with the two alarms respectively, indicate if an alarm has happened. These bits are set on an alarm condition regardless of whether the IRQ interrupt is enabled. The AL1 and AL0 bits in the status register are reset by the falling edge of the eighth clock of a read of the register containing the bits. Pulse Interrupt Mode The pulsed interrupt mode allows for repetitive or recurring alarm functionality. Hence an repetitive or recurring alarm can be set for every nth second, or nth minute, or nth hour, or nth date, or for the same day of the week. The pulsed interrupt mode can be considered a repetitive interrupt mode, with the repetition rate set by the time setting fo the alarm. The Pulse Interrupt Mode is enabled when the IM bit is set. IM Bit Interrupt/Alarm Frequency 0 Single Time Event Set By Alarm 1 Repetitive/Recurring Time Event Set By Alarm The Alarm IRQ output will output a single pulse of short duration (approximately 10-40ms) once the alarm condition is met. If the interrupt mode bit (IM bit) is set, then this pulse will be periodic. Programmable Frequency Output Bits—FO1, FO0 These are two output control bits. They select one of three divisions of the internal oscillator, that is applied to the PHZ output pin. Table 5 shows the selection bits for this output. When using the PHZ output function, the Alarm IRQ output function is disabled. Table 5. Programmable Frequency Output Bits FO1 FO0 Output Frequency (average of 100 samples) 0 0 Alarm IRQ output 0 1 32.768kHz 1 0 100Hz 1 1 1Hz ON-CHIP OSCILLATOR COMPENSATION Digital Trimming Register (DTR) — DTR2, DTR1 and DTR0 (Non-Volatile) The digital trimming Bits DTR2, DTR1 and DTR0 adjust the number of counts per second and average the ppm error to achieve better accuracy. DTR2 is a sign bit. DTR2=0 means frequency compensation is > 0. DTR2=1 means frequency compensation is < 0. DTR1 and DTR0 are scale bits. DTR1 gives 10 ppm adjustment and DTR0 gives 20 ppm adjustment. A range from -30ppm to +30ppm can be represented by using three bits above. Table 6. Digital Trimming Registers DTR Register DTR2 DTR1 DTR0 Estimated frequency PPM 0 0 0 0 0 1 0 +10 0 0 1 +20 0 1 1 +30 1 0 0 0 1 1 0 -10 1 0 1 -20 1 1 1 -30 Analog Trimming Register (ATR) (Non-volatile) Six analog trimming Bits from ATR5 to ATR0 are provided to adjust the on-chip loading capacitance range. The on-chip load capacitance ranges from 3.25pF to 18.75pF. Each bit has a different weight for capacitance adjustment. Using a Citizen CFS-206 crystal with different ATR bit combinations provides an estimated ppm range from +116ppm to -37ppm to the nominal frequency compensation. The combination of digital and analog trimming can give up to +146ppm adjustment. The on-chip capacitance can be calculated as follows: CATR = [(ATR value, decimal) x 0.25pF] + 11.0pF Note that the ATR values are in two’s complement, with ATR(000000) = 11.0pF, so the entire range runs from 3.25pF to 18.75pF in 0.25pF steps. The values calculated above are typical, and total load capacitance seen by the crystal will include approximately 2pF of package and board capacitance in addition to the ATR value. See Application section and Intersil’s application Note AN154 for more information. 13 FN8101.1 April 14, 2006 X1286 WRITING TO THE CLOCK/CONTROL REGISTERS Start Condition Changing any of the nonvolatile bits of the clock/ control register requires the following steps: All commands are preceded by the start condition, which is a HIGH to LOW transition of SDA when SCL is HIGH. The device continuously monitors the SDA and SCL lines for the start condition and will not respond to any command until this condition has been met. See Figure 5. – Write a 02h to the Status Register to set the Write Enable Latch (WEL). This is a volatile operation, so there is no delay after the write. (Operation preceeded by a start and ended with a stop). – Write a 06h to the Status Register to set both the Register Write Enable Latch (RWEL) and the WEL bit. This is also a volatile cycle. The zeros in the data byte are required. (Operation preceeded by a start and ended with a stop). – Write one to 8 bytes to the Clock/Control Registers with the desired clock, alarm, or control data. This sequence starts with a start bit, requires a slave byte of “11011110” and an address within the CCR and is terminated by a stop bit. A write to the CCR changes EEPROM values so these initiate a nonvolatile write cycle and will take up to 10ms to complete. Writes to undefined areas have no effect. The RWEL bit is reset by the completion of a nonvolatile write cycle, so the sequence must be repeated to again initiate another change to the CCR contents. If the sequence is not completed for any reason (by sending an incorrect number of bits or sending a start instead of a stop, for example) the RWEL bit is not reset and the device remains in an active mode. – Writing all zeros to the status register resets both the WEL and RWEL bits. – A read operation occurring between any of the previous operations will not interrupt the register write operation. SERIAL COMMUNICATION Interface Conventions The device supports a bidirectional bus oriented protocol. The protocol defines any device that sends data onto the bus as a transmitter, and the receiving device as the receiver. The device controlling the transfer is called the master and the device being controlled is called the slave. The master always initiates data transfers, and provides the clock for both transmit and receive operations. Therefore, the devices in this family operate as slaves in all applications. Clock and Data Stop Condition All communications must be terminated by a stop condition, which is a LOW to HIGH transition of SDA when SCL is HIGH. The stop condition is also used to place the device into the Standby power mode after a read sequence. A stop condition can only be issued after the transmitting device has released the bus. See Figure 5. Acknowledge Acknowledge is a software convention used to indicate successful data transfer. The transmitting device, either master or slave, will release the bus after transmitting eight bits. During the ninth clock cycle, the receiver will pull the SDA line LOW to acknowledge that it received the eight bits of data. Refer to Figure 6. The device will respond with an acknowledge after recognition of a start condition and if the correct Device Identifier and Select bits are contained in the Slave Address Byte. If a write operation is selected, the device will respond with an acknowledge after the receipt of each subsequent eight bit word. The device will acknowledge all incoming data and address bytes, except for: – The Slave Address Byte when the Device Identifier and/or Select bits are incorrect – All Data Bytes of a write when the WEL in the Write Protect Register is LOW – The 2nd Data Byte of a Status Register Write Operation (only 1 data byte is allowed) In the read mode, the device will transmit eight bits of data, release the SDA line, then monitor the line for an acknowledge. If an acknowledge is detected and no stop condition is generated by the master, the device will continue to transmit data. The device will terminate further data transmissions if an acknowledge is not detected. The master must then issue a stop condition to return the device to Standby mode and place the device into a known state. Data states on the SDA line can change only during SCL LOW. SDA state changes during SCL HIGH are reserved for indicating start and stop conditions. See Figure 4. 14 FN8101.1 April 14, 2006 X1286 Figure 4. Valid Data Changes on the SDA Bus SCL SDA Data Stable Data Change Data Stable Figure 5. Valid Start and Stop Conditions SCL SDA Start Stop Figure 6. Acknowledge Response From Receiver SCL from Master 1 8 9 Data Output from Transmitter Data Output from Receiver Start DEVICE ADDRESSING Following a start condition, the master must output a Slave Address Byte. The first four bits of the Slave Address Byte specify access to either the EEPROM array or to the CCR. Slave bits ‘1010’ access the EEPROM array. Slave bits ‘1101’ access the CCR. When shipped from the factory, EEPROM array is UNDEFINED, and should be programmed by the customer to a known state. Bit 3 through Bit 1 of the slave byte specify the device select bits. These are set to ‘111’. The last bit of the Slave Address Byte defines the operation to be performed. When this R/W bit is a one, then a read operation is selected. A zero selects a write operation. Refer to Figure 7. Acknowledge Following the Slave Byte is a two byte word address. The word address is either supplied by the master device or obtained from an internal counter. On powerup the internal address counter is set to address 0h, so a current address read of the EEPROM array starts at address 0. When required, as part of a random read, the master must supply the 2 Word Address Bytes as shown in Figure 7. In a random read operation, the slave byte in the “dummy write” portion must match the slave byte in the “read” section. That is if the random read is from the array the slave byte must be 1010111x in both instances. Similarly, for a random read of the Clock/Control Registers, the slave byte must be 1101111x in both places. After loading the entire Slave Address Byte from the SDA bus, the X1286 compares the device identifier and device select bits with ‘1010111’ or ‘1101111’. Upon a correct compare, the device outputs an acknowledge on the SDA line. 15 FN8101.1 April 14, 2006 X1286 Figure 7. Slave Address, Word Address, and Data Bytes (128 Byte pages) Device Identifier Array 1 0 1 0 CCR 1 1 0 1 0 A14 A13 A12 A7 A6 A5 D7 D6 D5 1 1 A11 A10 A9 A8 A4 A3 A2 A1 A0 D4 D3 D2 D1 D0 1 R/W Slave Address Byte Byte 0 Word Address 1 Byte 1 Word Address 0 Byte 2 Data Byte Byte 3 to the status register in two preceding operations to enable the write operation. See “Writing to the Clock/Control Registers.” Write Operations Byte Write For a write operation, the device requires the Slave Address Byte and the Word Address Bytes. This gives the master access to any one of the words in the array or CCR. (Note: Prior to writing to the CCR, the master must write a 02h, then 06h to the status register in two preceding operations to enable the write operation. See “Writing to the Clock/Control Registers.” Upon receipt of each address byte, the X1286 responds with an acknowledge. After receiving both address bytes the X1286 awaits the eight bits of data. After receiving the 8 data bits, the X1286 again responds with an acknowledge. The master then terminates the transfer by generating a stop condition. The X1286 then begins an internal write cycle of the data to the nonvolatile memory. During the internal write cycle, the device inputs are disabled, so the device will not respond to any requests from the master. The SDA output is at high impedance. See Figure 8. After the receipt of each byte, the X1286 responds with an acknowledge, and the address is internally incremented by one. When the counter reaches the end of the page, it “rolls over” and goes back to the first address on the same page. This means that the master can write 128 bytes to a memory array page or 8 bytes to a CCR section starting at any location on that page. For example, if the master begins writing at location 105 of the memory and loads 30 bytes, then the first 23 bytes are written to addresses 105 through 127, and the last 7 bytes are written to columns 0 through 6. Afterwards, the address counter would point to location 7 on the page that was just written. If the master supplies more than the maximum bytes in a page, then the previously loaded data is over written by the new data, one byte at a time. Refer to Figure 9. A write to a protected block of memory is ignored, but will still receive an acknowledge. At the end of the write command, the X1286 will not initiate an internal write cycle, and will continue to ACK commands. The master terminates the Data Byte loading by issuing a stop condition, which causes the X1286 to begin the nonvolatile write cycle. As with the byte write operation, all inputs are disabled until completion of the internal write cycle. Refer to Figure 10 for the address, acknowledge, and data transfer sequence. Page Write Stops and Write Modes The X1286 has a page write operation. It is initiated in the same manner as the byte write operation; but instead of terminating the write cycle after the first data byte is transferred, the master can transmit up to 127 more bytes to the memory array and up to 7 more bytes to the clock/control registers. (Note: Prior to writing to the CCR, the master must write a 02h, then 06h 16 Stop conditions that terminate write operations must be sent by the master after sending at least 1 full data byte and it’s associated ACK signal. If a stop is issued in the middle of a data byte, or before 1 full data byte + ACK is sent, then the X1286 resets itself without performing the write. The contents of the array are not affected. FN8101.1 April 14, 2006 X1286 Figure 8. Byte Write Sequence S t a r t Signals from the Master SDA Bus Word Address 1 Slave Address 1 1 110 S t o p Data 0 A C K Signals From The Slave Word Address 0 A C K A C K A C K Figure 9. Writing 30 bytes to a 128-byte memory page starting at address 105. 7 Bytes 23 Bytes Address Pointer Ends Here Addr = 7 Address =6 Address 105 Address 127 Figure 10. Page Write Sequence Signals from the Master SDA Bus 1 ≤ n ≤ 128 for EEPROM array 1 ≤ n ≤ 8 for CCR S t a r t Word Address 1 Slave Address 1 1 1 10 17 Data (1) S t o p Data (n) 0 A C K Signals from the Slave Word Address 0 A C K A C K A C K FN8101.1 April 14, 2006 X1286 clock and issuing a stop condition. Refer to Figure 11 for the address, acknowledge, and data transfer sequence. Acknowledge Polling Disabling of the inputs during nonvolatile write cycles can be used to take advantage of the typical 5mS write cycle time. Once the stop condition is issued to indicate the end of the master’s byte load operation, the X1286 initiates the internal nonvolatile write cycle. Acknowledge polling can begin immediately. To do this, the master issues a start condition followed by the Slave Address Byte for a write or read operation. If the X1286 is still busy with the nonvolatile write cycle then no ACK will be returned. When the X1286 has completed the write operation, an ACK is returned and the host can proceed with the read or write operation. Refer to the flow chart in Figure 12. Figure 12. Acknowledge Polling Sequence Byte load completed by issuing STOP. Enter ACK Polling Issue START Issue Slave Address Byte (Read or Write) Read Operations There are three basic read operations: Current Address Read, Random Read, and Sequential Read. ACK returned? Current Address Read Internally the X1286 contains an address counter that maintains the address of the last word read incremented by one. Therefore, if the last read was to address n, the next read operation would access data from address n+1. On power-up, the sixteen bit address is initialized to 0h. In this way, a current address read immediately after the power-onpower-on reset can download the entire contents of memory starting at the first location.Upon receipt of the Slave Address Byte with the R/W bit set to one, the X1286 issues an acknowledge, then transmits eight data bits. The master terminates the read operation by not responding with an acknowledge during the ninth Issue STOP NO YES nonvolatile write Cycle complete. Continue command sequence? NO Issue STOP YES Continue normal Read or Write command sequence PROCEED Figure 11. Current Address Read Sequence Signals from the Master SDA Bus Signals from the Slave 18 S t a r t S t o p Slave Address 1 1 1 11 A C K Data FN8101.1 April 14, 2006 X1286 activity will be ignored until a start is detected. This operation loads the new address into the address counter. The next Current Address Read operation will read from the newly loaded address. This operation could be useful if the master knows the next address it needs to read, but is not ready for the data. It should be noted that the ninth clock cycle of the read operation is not a “don’t care.” To terminate a read operation, the master must either issue a stop condition during the ninth cycle or hold SDA HIGH during the ninth clock cycle and then issue a stop condition. Random Read Sequential Read Random read operations allows the master to access any location in the X1286. Prior to issuing the Slave Address Byte with the R/W bit set to zero, the master must first perform a “dummy” write operation. Sequential reads can be initiated as either a current address read or random address read. The first data byte is transmitted as with the other modes; however, the master now responds with an acknowledge, indicating it requires additional data. The device continues to output data for each acknowledge received. The master terminates the read operation by not responding with an acknowledge and then issuing a stop condition. The master issues the start condition and the slave address byte, receives an acknowledge, then issues the word address bytes. After acknowledging receipt of each word address byte, the master immediately issues another start condition and the slave address byte with the R/W bit set to one. This is followed by an acknowledge from the device and then by the eight bit data word. The master terminates the read operation by not responding with an acknowledge and then issuing a stop condition. Refer to Figure 13 for the address, acknowledge, and data transfer sequence. The data output is sequential, with the data from address n followed by the data from address n + 1. The address counter for read operations increments through all page and column addresses, allowing the entire memory contents to be serially read during one operation. At the end of the address space the counter “rolls over” to the start of the address space and the X1286 continues to output data for each acknowledge received. Refer to Figure 14 for the acknowledge and data transfer sequence. In a similar operation called “Set Current Address,” the device sets the address if a stop is issued instead of the second start shown in Figure 13. The X1286 then goes into standby mode after the stop and all bus Figure 13. Random Address Read Sequence Signals from the Master S t a r t SDA Bus Slave Address 1 1 1 11 A C K A C K S t o p Slave Address 1 0 A C K Signals from the Slave Word Address 0 Word Address 1 1 110 S t a r t A C K Data Figure 14. Sequential Read Sequence A C K Slave Address Signals from the Master SDA Bus S t o p A C K A C K 1 A C K Signals from the Slave Data (1) Data (2) Data (n-1) Data (n) (n is any integer greater than 1) 19 FN8101.1 April 14, 2006 X1286 APPLICATION SECTION CRYSTAL OSCILLATOR AND TEMPERATURE COMPENSATION Intersil has now integrated the oscillator compensation circuity on-chip, to eliminate the need for external components and adjust for crystal drift over temperature and enable very high accuracy time keeping (<5ppm drift). The Intersil RTC family uses an oscillator circuit with on-chip crystal compensation network, including adjustable load-capacitance. The only external component required is the crystal. The compensation network is optimized for operation with certain crystal parameters which are common in many of the surface mount or tuning-fork crystals available today. Table 6 summarizes these parameters. Table 7 contains some crystal manufacturers and part numbers that meet the requirements for the Intersil RTC products. The turnover temperature in Table 7 describes the temperature where the apex of the of the drift vs. temperature curve occurs. This curve is parabolic with the drift increasing as (T-T0)2. For an Epson MC-405 device, for example, the turnover temperature is typically 25 deg C, and a peak drift of >110ppm occurs at the temperature extremes of -40 and +85 deg C. It is possible to address this variable drift by adjusting the load capacitance of the crystal, which will result in predictable change to the crystal frequency. The Intersil RTC family allows this adjustment over temperature since the devices include on-chip load capacitor trimming. This control is handled by the Analog Trimming Register, or ATR, which has 6 bits of control . The load capacitance range covered by the ATR circuit is approximately 3.25pF to 18.75pF, in 0.25pf increments. Note that actual capacitance would also include about 2pF of package related capacitance. Incircuit tests with commercially available crystals demonstrate that this range of capacitance allows frequency control from +116ppm to -37ppm, using a 12.5pF load crystal. In addition to the analog compensation afforded by the adjustable load capacitance, a digital compensation feature is available for the Intersil RTC family. There are three bits known as the Digital Trimming Register or DTR, and they operate by adding or skipping pulses in the clock signal. The range provided is ±30ppm in increments of 10ppm. The default setting is 0ppm. The DTR control can be used for coarse adjustments of frequency drift over temperature or for crystal initial accuracy correction. Table 7. Crystal Parameters Required for Intersil RTC’s Parameter Min Frequency Typ Max 32.768 Freq. Tolerance Turnover Temperature 20 Operating Temperature Range -40 Parallel Load Capacitance 25 Notes kHz ±100 ppm 30 °C 85 °C 12.5 Equivalent Series Resistance Units Down to 20ppm if desired Typically the value used for most crystals pF 50 kΩ For best oscillator performance Table 8. Crystal Manufacturers Manufacturer Part Number Temp Range +25°C Freq Toler. Citizen CM201, CM202, CM200S -40 to +85°C ±20ppm Epson MC-405, MC-406 -40 to +85°C ±20ppm Raltron RSM-200S-A or B -40 to +85°C ±20ppm SaRonix 32S12A or B -40 to +85°C ±20ppm Ecliptek ECPSM29T-32.768K -10 to +60°C ±20ppm ECS ECX-306/ECX-306I -10 to +60°C ±20ppm Fox FSM-327 -40 to +85°C ±20ppm 20 FN8101.1 April 14, 2006 X1286 A final application for the ATR control is in-circuit calibration for high accuracy applications, along with a temperature sensor chip. Once the RTC circuit is powered up with battery backup, the PHZ output is set at 32.768kHz and frequency drift is measured. The ATR control is then adjusted to a setting which minimizes drift. Once adjusted at a particular temperature, it is possible to adjust at other discrete temperatures for minimal overall drift, and store the resulting settings in the EEPROM. Extremely low overall temperature drift is possible with this method. The Intersil evaluation board contains the circuitry necessary to implement this control. frequency, noise can couple to the X1 or X2 pins and cause double-clocking. The layout in figure 15 can help minimize this by running the PHZ output away from the X1 and X2 pins. Also, minimizing the switching current at this pin by careful selection of the pullup resistor value will reduce noise. Intersil suggests a minimum value of 5.1k for 32.768kHz, and higher values (i.e. 20kΩ) for lower frequency PHZ outputs. For more detailed operation see Intersil’s application note AN154 on Intersil’s website at www.Intersil.com. Most electronic circuits do not have to deal with assembly issues, but with the RTC devices assembly includes insertion or soldering of a live battery into an unpowered circuit. If a socket is soldered to the board, and a battery is inserted in final assembly, then there are no issues with operation of the RTC. If the battery is soldered to the board directly, then the RTC device Vback pin will see some transient upset from either soldering tools or intermittent battery connections which can stop the circuit from oscillating. Once the battery is soldered to the board, the only way to assure the circuit will start up is to momentarily (very short period of time!) short the Vback pin to ground and the circuit will begin to oscillate. Layout Considerations The crystal input at X1 has a very high impedance and will pick up high frequency signals from other circuits on the board. Since the X2 pin is tied to the other side of the crystal, it is also a sensitive node. These signals can couple into the oscillator circuit and produce double clocking or mis-clocking, seriously affecting the accuracy of the RTC. Care needs to be taken in layout of the RTC circuit to avoid noise pickup. Below in Figure 15 is a suggested layout for the X1286 or X1288 devices. For other RTC products, the same rules stated above should be observed, but adjusted slightly since the packages and pinouts are slightly different. Assembly Figure 15. Suggested Layout for Intersil RTC in SO-8 Oscillator Measurements C1 0.1µF XTAL1 32.768kGz R1 10k U1 X1286/X1288 The X1 and X2 connections to the crystal are to be kept as short as possible. A thick ground trace around the crystal is advised to minimize noise intrusion, but ground near the X1 and X2 pins should be avoided as it will add to the load capacitance at those pins. Keep in mind these guidelines for other PCB layers in the vicinity of the RTC device. A small decoupling capacitor at the Vcc pin of the chip is mandatory, with a solid connection to ground. The X1286 product has a special consideration. The PHZ/IRQ- pin on the 8 Ld SOIC package is located next to the X2 pin. When this pin is used as a frequency output (PHZ) and is set to 32.768kHz output 21 When a proper crystal is selected and the layout guidelines above are observed, the oscillator should start up in most circuits in less than one second. Some circuits may take slightly longer, but startup should definitely occur in less than 5 seconds. When testing RTC circuits, the most common impulse is to apply a scope probe to the circuit at the X2 pin (oscillator output) and observe the waveform. DO NOT DO THIS! Although in some cases you may see a useable waveform, due to the parasitics (usually 10pF to ground) applied with the scope probe, there will be no useful information in that waveform other than the fact that the circuit is oscillating. The X2 output is sensitive to capacitive impedance so the voltage levels and the frequency will be affected by the parasitic elements in the scope probe. Applying a scope probe can possibly cause a faulty oscillator to start up, hiding other issues (although in the Intersil RTC’s, the internal circuitry assures startup when using the proper crystal and layout). The best way to analyze the RTC circuit is to power it up and read the real time clock as time advances, or if the chip has the PHZ output, look at the output of that pin on an oscilloscope (after enabling it with the control register, and using a pullup resistor for an opendrain output). Alternatively, the X1226/X1286/1288 FN8101.1 April 14, 2006 X1286 Figure 16. Supercapactor charging circuit devices have an IRQ- output which can be checked by setting an alarm for each minute. Using the pulse interrupt mode setting, the once-per-minute interrupt functions as an indication of proper oscillation. 2.7-5.5V VCC Vback Backup Battery Operation Supercapacitor Many types of batteries can be used with the Intersil RTC products. 3.0V or 3.6V Lithium batteries are appropriate, and sizes are available that can power a Intersil RTC device for up to 10 years. Another option is to use a supercapacitor for applications where Vcc may disappear intermittently for short periods of time. Depending on the value of supercapacitor used, backup time can last from a few days to two weeks (with >1F). A simple silicon or Schottky barrier diode can be used in series with Vcc to charge the supercapacitor, which is connected to the Vback pin. Do not use the diode to charge a battery (especially lithium batteries!). VSS Since the battery switchover occurs at Vcc=Vback0.1V (see Figure 16), the battery voltage must always be lower than the Vcc voltage during normal operation or the battery will be drained. The summary of conditions for backup battery operation is given in Table 9: Table 9. Battery Backup Operation 1. Example Application, Vcc = 5V, Vback = 3.0V Condition a. Normal Operation Vcc Vback Vtrip Iback 5.00 3.00 4.38 <<1µA Notes b. Vcc on with no battery 5.00 0 4.38 0 c. Backup Mode 0-1.8 1.8-3.0 4.38 <2µA Vcc Vback Vtrip Iback a. Normal Operation 3.30 3.00 2.65 <<1µA b. Vcc on with no battery 3.30 0 2.65 0 c. Backup Mode 0-1.8 1.8-3.0* 2.65 <2µA* Timekeeping only 2.65 - 3.30 > Vcc 2.65 up to 3mA Internal Vcc=Vback Timekeeping only 2. Example Application, Vcc = 3.3V,Vback = 3.0V Condition d. UNWANTED - Vcc ON, Vback powering *since Vback>2.65V is higher than Vtrip, the battery is powering the entire device 22 FN8101.1 April 14, 2006 X1286 One way to prevent operation in battery backup mode above the Vtrip level is to add a diode drop (silicon diode preferred) to the battery to insure it is below Vtrip. This will also provide reverse leakage protection which may be needed to get safety agency approval. PERFORMANCE DATA IBACK Performance IBACK vs. Temperature Multi-Lot Process Variation Data 1.4 3.3V 1.2 1.8V 1.0 IBACK (µA) Referring to Figure 16, Vtrip applies to the “Internal Vcc” node which powers the entire device. This means that if Vcc is powered down and the battery voltage at Vback is higher than the Vtrip voltage, then the entire chip will be running from the battery. If Vback falls to lower than Vtrip, then the chip shuts down and all outputs are disabled except for the oscillator and timekeeping circuitry. The fact that the chip can be powered from Vback is not necessarily an issue since standby current for the RTC devices is <2µA for this mode (called “main timekeeping current” in the data sheet). Only when the serial interface is active is there an increase in supply current, and with Vcc powered down, the serial interface will most likely be inactive. 0.8 0.6 0.4 0.2 0 -40 25 60 Temperature °C 85 One mode that should always be avoided is the operation of the RTC device with Vback greater than both Vcc and Vtrip (Condition 2d in Table 9). This will cause the battery to drain quickly as serial bus communication and non-volatile writes will require higher supplier current. 23 FN8101.1 April 14, 2006 X1286 TSSOP Package Outline Drawing NOTE: The package drawing shown here may not be the latest version. To check the latest revision, please refer to the Intersil website at http://www.intersil.com/design/packages/index.asp 24 FN8101.1 April 14, 2006 X1286 8-Lead Plastic, EIAJ SOIC, Package Code A8 0.020 (.508) 0.012 (.305) .213 (5.41) .205 (5.21) .330 (8.38) .300 (7.62) Pin 1 ID .050 (1.27) BSC .212 (5.38) .203 (5.16) .080 (2.03) .070 (1.78) .013 (.330) .004 (.102) .010 (.254) .007 (.178) 0° - 8° Ref. .035 (.889) .020 (.508) NOTES: 1. ALL DIMENSIONS IN INCHES (IN PARENTHESES IN MILLIMETERS) 2. PACKAGE DIMENSIONS EXCLUDE MOLDING FLASH All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems. Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com 25 FN8101.1 April 14, 2006