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EM MICROELECTRONIC - MARIN SA
V3025
Very Low Power 8-Bit 32 kHz RTC Module with Digital Trimming, User RAM and Battery Switch-over
Description The V3025 is a low power CMOS real time clock with an integrated battery switch-over. The standby current is typically 2.5 µA and the access time is 50 ns. The interface is a multiplexed address and data 8 bits bus. Multiplexing of address and data is handled by the input line A /D. There are no busy flags in the V3025, internal time update cycles are invisible to the user's software. Time data can be read from the V3025 in 12 or 24 hour data formats. An external signal puts the V3025 in standby mode. Even in standby, the V3025 pulls the IRQ pin active low on an internal alarm interrupt. Calendar functions include leap year correction and week number calculation. The V3025 can be synchronized to an external 50 Hz signal or to the nearest second or minute. The integrated battery switch-over supply the real time clock part by VDD as long as VDD is higher than VBAT. When VDD decreases under VBAT, the output PFO comes active and the real clock is supplied by the battery or the supercap. Applications Industrial controllers Alarm systems with periodic wake up PABX and telephone systems Point of sale terminals Automotive electronics Personal computers Features Built-in quartz with digital trimming temperature compensation facilities INTEL and MOTOROLA interface compatibility 15 ns typical access time at 5.0V 1.2 µA typical standby current at 3.0V Wide supply voltage range, 2.0 ≤ VDD ≤ 5.5V Integrated battery switch-over Battery voltage range, 2.0 ≤ VBAT ≤ 4.0V No busy state No external components required BCD format Frequency measurements Time set lock mode Week number calculation Clock counts up to 99 years Leap year correction 12 or 24 hour data format Output programmable interrupts Alarm interrupt, programmable up to one month Timer interrupt, programmable up to 24 hours Time to 1/100 of a second To external time reference synchronisation 50 Hz or nearest s/min synchronisation Power fail input PFI Power fail output or Reset output PFO Tri-state bus capability when power fail ( PFI = 0) User RAM Temperature range -40 to +85°C Package SO28 and
Typical Operating Configuration
Pin Assignment SO28
SYNC PFI AD0 AD1 AD2 AD3 A/D IRQ VOUT VSS VSS VSS VSS VSS VBAT AD7 AD6 AD5 AD4 RD WR
V3025
CS PFO VDD VDD VDD VDD VDD
Fig. 1 Copyright © 2004, EM Microelectronic-Marin SA 1
Fig. 2
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V3025
Absolute Maximum Ratings Parameter Symbol Maximum voltage at VDD and VSUPmax VBAT Max. voltage at remaining pins VSUP Min. voltage on all pins Vmin Maximum storage temperature TSTOmax Minimum storage temperature TSTOmin Maximum electrostatic VSmax discharge to MIL-STD-883C method 3015.7 with ref. to VSS Maximum soldering conditions TSmax Shock resistance Conditions VSS + 7.0V VDD + 0.3V VSS – 0.3V +125°C -55°C 1000V 250°C x 10s 5000 g. 0.3ms, ½ sine
Table 1
Handling Procedures This device has built-in protection against high static voltages or electric fields; however, anti-static precautions must be taken as for any other CMOS component. Unless otherwise specified, proper operation can only occur when all terminal voltages are kept within the voltage range. Unused inputs must always be tied to a defined logic voltage level. Operating Conditions
Parameter Operating temperature Main supply voltage Battery supply voltage Logic supply voltage Supply voltage dv/dt (power-up & down) Decoupling capacitor Symbol TA VDD VBAT VSUP dv/dt Min -40 2 2 2.0 Typ Max +85 5.5 4 5.5 6 Unit °C V V V V/µs
5.0
Stresses above these listed maximum ratings may cause permanent damages to the device. Exposure beyond specified operating conditions may affect device reliability or cause malfunction.
100
nF Table 2
Electrical Characteristics VDD = 5.0V ±10%, VBAT = 3V, TA = -40 to +85°C, unless otherwise specified Parameter Symbol Test Conditions Standby current (note 1) IDD1 VDD = 3 V, VBAT = 0V, PFI = 0 IDD2 VDD = 5.5 V, PFI = 0 Standby current (note 1) Dynamic current (note 2)
IRQ (open drain) Output low voltage Output low voltage Inputs and Outputs Input logic low Input logic high Output logic low Output logic high PFI activation voltage PFI hysteresis
Min
IBAT IDYN
VDD = 0 V, PFI = 0 CS = 4 MHz, RD = VSS
WR = VDD
Typ 1.2 2.5 1.3
Max 10 15 10 1.5
Unit µA µA µA mA
VOL VOL VIL VIH VOL VOH VPFL VH ILS IIN ITS VSTA VSTA TSTA ∆f/f fsta tsta tag ASW
IOL = 6 mA IOL = 1 mA, VDD = 2 V TA = +25°C TA = +25°C IOL = 6 mA IOH = 6 mA TA = +25°C VILS = 0.8 V VSS < VIN < VDD CS = 1 TA ≥ +25°C 2 2.5 TA = +25°C addr. 10 hex = 00 hex 2.0 ≤ VDD ≤ 5.5 V (note 3) addr. 10 hex = 00 hex TA = +25°C, first year VBAT = 3V, 10 pulses of VDD switching between 2 to 5V in 70ms 1 210 (note 4) 1 see Fig.6 0.2 20 0.8 VSUP
0.4 0.4 0.2 VSUP 0.4 2.4 0.5 VDD 100 40 5 5 1000 1000
V V V V V V V mV µA nA nA V V s ppm ppm/V ppm ppm/year ppm
Pullup on SYNC Input leakage Output tri-state leakage Oscillator Characteristics Starting voltage Frequency Characteristics Start-up time Frequency tolerance Frequency stability Temperature stability Aging Accuracy versus switchover
150
251 5 ±5
Table 3
Note 1: With PFO = 0 (VSS) all I/O pads can be tri-state, tested. With PFO = 1 (VSUP), CS = 1 (VDD) and all other I/O pads fixed to VSUP or VSS: same standby current, not tested. Note 2: All other inputs to VDD and all outputs open. Note 3: At a given temperature. Note 4: See Fig. 5
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V3025
Switch-over Electrical Characteristics TA = -40 to +85°C, inputs to VDD, outputs not connected, unless otherwise specified Parameter Symbol Test Conditions ON resistance of VDD to VOUT RVDD VDD = 3V, VBAT = 0V, IOUT = 100mA ON resistance of VBAT to VOUT RBAT VDD = 0V, VBAT = 3V, IOUT = 20mA VDD voltage over VBAT for VSVDD VBAT = 3V, VOUT open switching VDD voltage under VBAT for VSBAT VBAT = 3V, VOUT open switching VDD rising edge switching TRDD VBAT = 3V, VDD rise from 2.8V to 3.5V delay to PFO and VOUT TFDD VDD falling edge switching VBAT = 3V, VDD falling from 3.5V to 2.8V delay to PFO and VOUT Min Typ 4 24 3.21 3.08 14 8 Max 8 40 3.45 3.18 100 60 Unit Ω Ω V V µs µs
Table 4
3.00 2.98
Timing Characteristics VDD = 5.0V ±10%, VBAT = 0V, VSS = 0V and TA = -40 to +85°C Parameter Symbol Test Conditions Chip select duration, write cycle tCS Write pulse duration Time between two transfers RAM access time (note 1) Data valid to Hi-impedance (note 2) Write data settle time (note 3) Data hold time (note 4) Advance write time
PF response delay
Min 50 50 100
Typ
Max
Unit ns ns ns
tWR tW tACC tDF tDW tDH tADW tPF tR tF tA tA
/Ds /Dt
CLOAD = 50pF 10 50 10 10
50 30
60 40
ns ns ns ns ns
100 200 200 5 10
ns ns ns ns ns
Table 4
Rise time (all inputs) Fall time (all inputs)
CS delay after A /D (note 5) CS delay to A /D
Note 1: tACC starts from RD ( DS ) or CS , whichever activates last Typically, tACC = 5 + 0.9 CEXT in ns; where CEXT (external parasitic capacitance) is in pF Note 2: tDF starts from RD ( DS ) or CS , whichever deactivates first Note 3: tDW ends at WR (R/ W ) or CS , whichever deactivates first Note 4: tDH starts from WR (R/ W ) or CS , whichever deactivates first Note 5: A /D must come before a CS and RD or a CS and WR combination. The user has to guarantee this.
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V3025
Typical VDD Current vs. Temperature
Fig. 3
Typical VBAT Current vs. Temperature
Fig. 4
Typical Frequency on IRQ
Fig. 5
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V3025
Module Characteristic
∆F ppm 2 = -0.038 (T – TO) ± 10% 2 FO °C ∆F/FO = the ratio of the change in frequency to the nominal value expressed in ppm (it can be thought of as the frequency deviation at any temperature) the temperature of interest in °C the turnover temperature (25 ± 5°C)
T TO
= =
To determine the clock error (accuracy) at a given temperature, add the frequency tolerance at 25°C to the value obtained from the formula above.
Fig. 6
Typical VDD Switch Resistance vs. Temperature
Fig. 7
Typical Battery Switch Resistance vs. Temperature
Fig. 8
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V3025
Timing Waveforms Read Timing for Intel ( RD and WR Pulse) and Motorola ( DS or RD pin tied to CS and R/ W )
Fig. 9a
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V3025
Intel Interface Write Timing
Fig. 9b
Write
Fig. 9c
Read
Fig. 9d
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V3025
Motorola Interface Motorola Write
Fig. 9e
Write
Fig. 9f
Read
Fig. 9g
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V3025
General Block Diagram
Fig. 10
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V3025
Pin Description
SO28 Package Pin 1 Name
SYNC PFI
Description Time synchronization
I I I/O I/O I/O I/O I O O GND PWR O I I I I/O I/O I/O I/O PWR
Table 5
2 3 4 5 6 7 8 9 10-14 15-19 20 21 22 23 24 25 26 27 28
AD0 AD1 AD2 AD3
A /D IRQ VOUT VSS VDD PFO CS WR RD
Power fail Bit 0 from MUX address / data bus Bit 1 from MUX address / data bus Bit 2 from MUX address / data bus Bit 3 from MUX address / data bus Address / data decode Interrupt request Switch-over output Supply ground (substrate) Positive supply terminal Power fail output Chip select
WR (Intel) or R/ W (Motorola) RD (Intel) or DS (Motorola) Bit 4 from MUX address / data bus Bit 5 from MUX address / data bus Bit 6 from MUX address / data bus Bit 7 from MUX address / data bus Battery supply
Initialisation When power is first applied to the V3025 all registers have a random value. To initialise the V3025, software must first write a 1 to the initialisation bit (addr. 2 bit 4) and then a 0. This sets the Frequency Tuning bit and clears all other status bits. The time and date parameters should then be loaded into the RAM (addr. 20 to 28 hex) and then transferred to the reserved clock area using the clock command followed by a write. The digital trimming register must then be initialised by writing 210 (D2 hex) to it, if Frequency Tuning is not required. After having written a value to the digital trimming register the frequency tuning mode bit can be cleared. RAM Configuration The RAM area of the V3025 has a reserved clock and time area, a data space, user RAM and an address command space (see Table 10 or Fig. 10). The reserved clock and timer area is not directly accessible to the user, it is used for internal time keeping and contains the current time and date plus the timer parameters. Data Space All locations in the data space are Read/Write. The data space is directly accessible to the user and is divided into five areas: Status Registers – three registers used for status and control data for the device (see Table 7, 8 and 9). Reserved bits must be set to 0. Digital Trimming Register – a special function described under "Frequency Tuning". Time and Date Registers – 9 time and date locations which are loaded with, either the current time and date parameters from the reserved clock area or the time and date parameters to be transferred to the reserved clock area. Alarm Registers – 5 locations used for setting the alarm parameters. Timer Registers – 4 locations which are loaded with either the timer parameters from the reserved timer area or the timer parameters to be transferred to the reserved timer area. User RAM The V3025 has 16 bytes of general purpose RAM available for the users applications. This RAM block is located at addresses 50 to 5F hex and is maintained even in the standby mode ( PFI active). The commands, or the time set lock bit, have no effect on the user RAM block. Reading or writing to the user RAM is similar to reading or writing to any system RAM address.
AD4 AD5 AD6 AD7 VBAT
Functional Description Power Supply, Data Retention and Standby The V3025 is put in standby mode by activating the PFI input. When pulled logic low, PFI will disable the input lines, and immediately take to high impedance the lines AD 0-7. Input states must be under control whenever PFI is deactivated. If no specific power fail signal can be provided, PFI can be tied to the system RESET . Even
in standby the interrupt request pin IRQ will pull to ground upon an unmasked alarm interrupt occurring.
Switch-over The switch-over supplies the core of the RTC. The I/O pads are supplied by VDD, except for IRQ and SYNC .
The SYNC input is internally pulled-up to VOUT, IRQ can be externally pulled-up between 2 and 5.5V. The switchover circuitry works in recovery mode. During switching, both transistors (VDD to VOUT and VBAT to VOUT) are ON. This is to guarantee that the RTC is always supplied. The power fail signal becomes active ( PFO = 0) when VDD < VBAT (see Table 4).
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V3025
Status Words RAM Map Address Dec Parameter Hex Range Data Space Status 00 00 status 0 01 01 status 1 02 02 status 2 Special purpose 16 10 digital trimming Clock 32 20 1/100 second 33 21 seconds 34 22 minutes 35 23 hours (note 1) 36 24 date 37 25 month 38 26 year 39 27 week day 40 28 week number Alarm 48 30 1/100 second 49 31 seconds 50 32 minutes 51 33 hours (note 1 & 2) 52 34 date Timer 64 40 1/100 second 65 41 seconds 66 42 minutes 67 43 hours User RAM 80 50 user RAM, byte 0 81 51 user RAM, byte 1 82 52 user RAM, byte 2 83 53 user RAM, byte 3 84 54 user RAM, byte 4 85 55 user RAM, byte 5 86 56 user RAM, byte 6 87 57 user RAM, byte 7 88 58 user RAM, byte 8 89 59 user RAM, byte 9 90 5A user RAM, byte 10 91 5B user RAM, byte 11 92 5C user RAM, byte 12 93 5D user RAM, byte 13 94 5E user RAM, byte 14 95 5F user RAM, byte 15 Address Command Space 240 F0 clock and timer transfer 241 F1 clock transfer 242 F2 timer transfer
0-255 00-99 00-59 00-59 00-23 01-31 01-12 00-99 01-07 00-53 00-99 00-59 00-59 00-23 01-31 00-99 00-59 00-59 00-23
Table 7
Table 8
Table 9
Address Command Space This space contains the three commands used for carrying out the transfers between the Time and Data Register and / or the Timer Registers and the reserved clock and timer area.
Table 10
Note 1: The MSB (bit 7) of the hours byte (addr. 23 hex for the clock and 33 hex for the alarm) are used as AM/PM indicators in the 12 hour time data format and reading of the hours byte must be preceded by masking of the AM/PM bit. A set AM/PM bit indicates PM. In the 24 hour time data format the bit will always be zero. Note 2: The alarm hours, addr. 33 hex, must always be rewritten after a change between 12 and 24 hour modes.
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V3025
Communication Data transfer is in 8 bit parallel form. All time data is in packed BCD format with tens data on lines AD7-4 and units on lines AD3-0. To access information within the RAM (see Fig.10) first write the RAM address, then read or write from or to this location. Fig.11 shows the two steps needed. The lines AD0-7 will be treated as an address when pin A /D is low, and as data when A /D is high. Pin A /D must not change state during any single read or write access. One line of the address bus (e.g. A0) can be used to implement the A /D signal (see "Typical Operating Configuration", Fig.1). Until a new address is written, data accesses ( A /D high) will always be to the same RAM address. Communication Sequence
locations is transferred to the reserved clock and/or timer area.
Clock and Calendar The time and date locations in RAM (see Table 10) provide access to the 1/100 seconds, seconds, minutes, hours, date, month, year, week day and week number. These parameters have the ranges indicated in Table 10. The V3025 may be programmed for 12 or 24 hour time format (see section "12/24 Data Format"). If a parameter is found to be out of range, it will be cleared when the units value on its being next incremented is equal to or greater than 9 eg. B2 will be set to 00 after the units have incremented to 9 (ie. B9 to 00). The device incorporates leap year correction and week number calculation at the beginning of a year. If the first day of the year is day 05, 06 or 07 of the week, then it is given a zero week number, otherwise it becomes week 1. Week days are numbered from 1 to 7 with Monday as day 1. Reading of the current time and date must be preceded by a clock command. The time and date from the last clock command is held unchanged in RAM. When transferring data to the reserved clock and timer area remember to clear the time set lock bit first. Timer The timer can be used either for counting elapsed time, or for giving an interrupt ( IRQ ) on being incremented from 23:59:59:99 to 00:00:00:00. The timer counts up with a resolution of 1/100 second in the timer reserved areas. The timer enable/disable bit (addr. 00 hex, bit 3) must be set by software to allow the timer to be incremented. The timer is incremented in the reserved timer area, every internal time update (10 ms). The timer flag (addr. 01 hex, bit 6) is set when the timer rolls over from 23:59:59:99 to 00:00:00:00 and the IRQ becomes active
A/D =0
A/D =1
Fig. 11
Access Considerations The communication sequence shown in Fig.11 is reentrant. When the address is written to the V3025 (ie. first step of the communication sequence) it is stored in an internal address latch. Software can read the internal address latch at any time by holding the A /D line low during a read from the V3025. So, for example, an interrupt routine can read the address latch and push it on to a stack, popping it when finished to restore the V3025. N.B. Alarm and timer interrupt routines can reprogram the alarm and timer without it being necessary to read or reprogram the clock. Commands The commands allow software to transfer the clock and timer parameters in a sequence (eg. seconds, minutes, hours, etc.) without any danger of an internal time update with carry over corrupting the data. They also avoid delaying internal time updates while using the V3025, as updates occurring in the reserved clock and timer area are invisible to software. Software writes or reads parameters to or from the RAM only. There are three commands that occupy the command address space in the RAM. The function of these commands is to transfer data from the reserved clock and timer area to the RAM or to transfer data in the opposite direction, from the RAM to the reserved clock and timer area. The commands take place in two steps as do all other communications. The command address is sent with A /D low. This is followed by either a read ( RD ) or a write ( WR ) , with A /D high, to determine the direction of the transfer. If the second step is a read then the data is transferred from the reserved clock and timer area to the RAM and if the second step is a write then the data that has already been loaded into the RAM clock and/or timer
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if the timer mask bit (addr. 01, bit 2) is set. The IRQ will remain active until software acknowledges the interrupt by clearing the timer flag. The timer is incremented in the standby mode, however it will not cause IRQ to become active until power (VDD) has been restored.
Note: The user should ensure that a time lapse of at least 60 microseconds exists between the falling edge of the IRQ and the clearing of the timer flag.
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V3025
Reading the Clock
[Pin 7 = A/D] A/D = 0 Start Write clock command (addr. F1 hex) to the V3025
Setting the Timer (Time Set Lock Bit = 0)
[Pin 7 = A/D] A/D = 0 Start Write 1/100 sec. address (40 hex) to the V3025 Write 1/100 sec. data to the RAM Write sec. address (41 hex) to the V3025
A/D = 1
Read data from the V3025 to copy the timer parameters from the reserved clock area to the RAM.
A/D = 1
A/D = 0
A/D = 0
Write 1/100 sec. address (20 hex) to the V3025 Read 1/100 sec. data from the RAM Write sec. address (21 hex) to the V3025
A/D = 1
Write sec. data to the RAM
A/D = 1
A/D = 0
Write min. address (42 hex) to the V3025
A/D = 0
A/D = 1
Write min. data to the RAM
A/D = 1
Read sec. data from the RAM
A/D = 0
Write hours address (43 hex) to the V3025
A/D = 0
Write min. address (22 hex) to the V3025
A/D = 1
Write hours data to the RAM
A/D = 1
Read min. data from the RAM
A/D = 0
Write timer command (addr. F2 hex) to the V3025 Write F2 hex to the V3025 to copy the timer parameters from RAM to the reversed timer area End
End A/D = 1
Fig. 12
Fig. 13
Note: Commands are only valid as commands when the A /D line is low. Writing F2 hex with the A /D line high, as in the last box of Fig. 11, serves only to activate the V3025 write pin which determines the direction of transfer.
Alarm An alarm date and time may be preset in RAM addresses 30 to 34 hex. The alarm function can be activated by setting the alarm enable / disable bit (addr. 00 hex, bit 2). Once enabled the preset alarm time and date are compared, every internal time update cycle (10 ms), with the clock parameters in the reserved clock area. When the clock parameters equal the alarm parameters the alarm flag (addr. 01 hex, bit 5) is set. If the alarm mask bit (addr. 01 hex, bit 1) is set, the IRQ pin goes active. The alarm flag indicates to software the source of the interrupt. IRQ will remain active until software acknowledges the interrupt by clearing the alarm flag. If the alarm is enabled, and an alarm address set to FF hex, this parameters is not compared with the associated clock
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parameter. Thus it is possible to achieve a repeat feature where an alarm occurs every programmed number of seconds, or seconds and minutes, or seconds, minutes and hours. The V3025 pulls the open drain IRQ line active low during standby when an alarm interrupt occurs. If the 12/24 hour mode is changed then the alarm hours must be re-initialised. Note: The user should ensure that a time lapse of at least 60 microseconds exists between the falling edge of the IRQ and the clearing of the alarm flag.
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V3025
IRQ
The IRQ output is used by 4 of the V3025's features. These are: 1. Pulse, to provide periodic interrupts to the microprocessors at pre-programmed intervals; 2. Alarm to provide an interrupt to the microprocessor at a pre-programmed time and date; 3. Timer, to provide an interrupt to the microprocessor when the time rolls over from 23:59:59:99 to 00:00:00:00; and 4. Frequency trimming (see section "Frequency Trimming"). The first 3 features listed are similar in the way they provide interrupts to the microprocessor. Each of the 3 has an enable / disable bit, a flag bit, and an interrupt mask bit. The enable / disable bit allows software to select a feature or not. A set flag bit indicates that an enable feature has reached its interrupt condition. Software must clear the flag bit. The interrupt mask bit allows or disallows the IRQ output to become active when the flag bit is se. The IRQ output becomes active whenever any interrupt flag is set which also has its mask bit set. For all sources of maskable interrupts within the V3025, the IRQ output will remain active until software clears the interrupt flag. The IRQ output is the logical OR of all the unmasked interrupt flags. The IRQ output is open drain so an external pullup to VDD is needed. In standby ( PF active) the IRQ output will be active if the alarm mask bit (addr, 01 hex, bit 1) is set and the alarm flag is also set. The timer or the pulse feature cannot cause the IRQ output to become active while in standby.
Snychronization There are 3 ways to synchronize the V3025. It can be synchronized to 50 Hz, the nearest second, or the nearest minute. Synchronization mode is selected by setting one of the bits 5 to 7 at addr. 02 hex, in accordance with Table 8. If more than one bit is set then all the synchronization bits are disabled. If the SYNC input is set low for longer than 200 µs, while in the synchronization mode, the clock will synchronize to the falling edge of the signal. Synchronization to the nearest second implies that the 1/100 seconds are cleared to zero and if the contents were > 50, the seconds register is incremented. Synchronization to the nearest minute implies that the seconds are cleared to zero and if the contents were > 30, the minutes register is incremented. Fractions of seconds are cleared. Pulse There are 4 programmable pulse frequencies available on the V3025, these are every 10 ms, 100 ms, second or minute. The pulse feature is activated by setting the pulse enable / disable bit at address 00, bit 1. The pulse frequency is selected by setting one of the bit 0 to 3 at address 02 hex (see Table 9). If more than one of the pulse bits is set then the feature is disabled. At the selected interval the pulse flag bit (addr. 01 hex, bit 4) is set. If the pulse mask bit (addr. 01 hex, bit 0) is set then the IRQ pin goes active. The pulse flag indicates to
while in standby. Upon power restoration the pulse feature is enabled if enabled prior to standby. See also the section "Frequency Tuning". Note: The user should ensure that a time lapse of at least 60 microseconds exists between the falling edge of the IRQ and the clearing of the pulse flag.
Time Set Lock The time set lock control bit is located at address 00 hex, bit 5 (see Table 7). When set by software, this bit disables any transfer from the RAM to the reserved clock and timer area as well as inhibiting any write to the digital trimming register at address 10 hex. When the time set lock bit is set the following transfer operations are disabled:
The clock command followed by write, the timer command followed by write, the clock and timer command followed by write, and writing to the digital trimming register A set bit prevents unauthorized overwriting of the reserved clock and timer area. Reading of the reserved clock and timer area, using the commands, is not affected by the time set lock bit. Clearing the time set lock bit by software will re-enable the above listed commands. On initialisation the time set lock bit is cleared. The time set lock bit does not affect the user RAM (addr. 50 to 5F hex).
Frequency Tuning The V3025 offers a key feature called "Digital Trimming", which is used for the clock accuracy adjustment. Unlike the traditional capacitor trimming method which tunes the crystal oscillator, the digital trimming acts on the divider chain, allowing the clock adjustment by software. The oscillator frequency itself is not affected. The Principle of Digital Trimming With the digital trimming disabled (ie. digital trimming register set to 00 hex), the oscillator and the first stages of the divider chain will run slightly too fast (typ. 210 ppm: ppm = parts per million), and will generate a 100 Hz signal with a frequency of typically 100.021 Hz. To correct this frequency, the digital trimming logic will inhibit every 31 seconds, a number of clock pulses, as set in the digital trimming register. Since the duration of 31 seconds corresponds to 1'015'808 oscillator cycles, the digital trimming has a resolution of 0.984 ppm. In other words every increment by 1 of the digital trimming value will slow down the clock by 0.984 ppm, which permits the accuracy of ± 0.5 ppm to be reached. Note that a 1 ppm error will result in a 1 second difference after 11.5 days, or a 1 minute difference after 694 days ! The trimming range of the V3025 is from 0 to 251 ppm. The 251 ppm correction is obtained by writing 255 (FFhex) into the digital trimming register.
software the source of the interrupt. IRQ will remain active until software acknowledges the interrupt by clearing the pulse flag. The pulse feature is disabled
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V3025
How to Determine the Digital Trimming Value The value to write into the digital trimming register has to be determined by the following procedure:
1. Initialise the V3025 by writing a 1 and then a 0 into the "Initialisation Bit" of the status register 2 (addr. 02 hex, bit 4). This activates the frequency tuning mode in status register 0 (addr. 00 hex, bit 1) and clears the other status bits. 2. Write the value 00 hex into the digital trimming register (addr 10 hex). From now, the IRQ output (open drain) will deliver the 100 Hz signal, which has a 20% duty cycle. 3. Measure the duration of 21 pulses at the IRQ output, with the trigger set for the falling edge. It is possible also to divide the IRQ frequency by 21, using a TTL or CMOS external circuit. 4. Compute the frequency error in ppm: 210ms − measured value in ms 6 x 10 freq. error = 210ms 5. Compute the corrective value to write into the digital trimming register. Digital trimming value = frequency error / 0.984 6. Write this value into the digital trimming register. 7. Switch off the frequency tuning mode in status 0 (addr. 00 hex, bit 0 set to 0).
12 / 24 Hour Data Format The V3025 can run in 12 hour data format. On initialisation the 12/24 hour bit addr. 00 bit 4 is cleared putting the V3025 in 24 hour data format. If the 12 hour data format is required then bit 4 at addr. 00 must be set. In the 12 hour data format the AM/PM indicator is the MSB of the hours register addr. 23 bit 7. A set bit indicates PM. When reading the hours in the 12 hour data format software should mask the MSB of the hours register. In the 24 hour data format the MSB is always zero. The internal clock registers change automatically between 12 and 24 hour mode when the 24/12 hour bit is changed. The alarm hours however must be rewritten. Test From the various test features added to the V3025 some may be activated by the user. Table 7 shows the test bits. Table 11 shows the three available modes and how they may be activated. The first accelerates the incrementing of the parameters in the reserved clock and timer area by 32. The second causes all clock and timer parameters, in the reserved clock and timer area, to be incremented in parallel at 100 Hz with no carry over, ie. independently of each other. The third test mode combines the previous two resulting in parallel incrementing at 3.2 kHz. While test bit 1 is set (addr. 00 hex, bit 7) the digital trimming action is disabled and no pulses are removed from the divider chain. Test bit 0 (addr. 00 hex, bit 6) can be combined with digital trimming (see section "Frequency Tuning"). To leave test, the test bits (addr 00 hex, bits 6 and 7) must be cleared by software. Test corrupts the clock and timer parameters and so all parameters should be re-initialised after a test session. Test Modes
Addr. 00hex bit 7 0 0 1 Addr. 00hex bit 6 0 1 0 Function Normal operation Acceleration by 32 Parallel increment of all clock and timer parameters at 100 Hz with no carry over; dependent on the status of bit 3 at address 00 hex Parallel increment of all clock and timer parameters at 3.2 kHz with no carry over; dependent on the status of bit 3 at address 00 hex Table 11
The Real Time Clock circuit will now run accurately at an operating temperature equal to the calibration temperature. If the operating temperature differs from the one at calibration time, the graphs shown on Fig. 5 and 6 will help in determining the definitive value. If the mean operating temperature of the equipment is not known at calibration time, the equipment user will do the final correction with a software provided by the system designer. To avoid the calibration procedure, it is possible also to set the digital trimming register to 210 (D2 hex) as a standard starting value, and let the final equipment user perform the final adjustment on site, which will take the real temperature into account.
Time Correction at Room Temperature Let us consider that the duration of 21 pulses of the IRQ signal is 209.97 ms at room temperature.
The frequency error is: (210 – 209.97) / 210 x 1E + 06 = 142.857 ppm The value for the digital trimming register is: 142.857 / 0.984 = 145.18, rounded up to 145 ppm (91 hex)
Time Correction with Change of Temperature If the mean temperature on site is known to be 45°C, the frequency error determined at room temperature has to be modified using the graphs or the equation of Fig. 6
1
1
∆f/f = -0.038 x (45-25) = 15.2 ppm The trimming value for 45°C will be: (142.857 ppm – 15.2 ppm) / 0.984 = 129.73, rounded to 130 (82 hex)
2
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V3025
Typical Operating Configuration
Fig. 14
Process Application
•
Temperature sensor
• •
Controller
Solenoid valve
The formula in Fig. 5 is used by software to continually update the digital trimming register and so compensate the V3025 for the ambient temperature. The timer is used to measure the duration the valve is on. The alarm feature is used to turn the controller power on and off at the time programmed by software. The V3025 pulls IRQ active low on an alarm even in standby and thus can control the power on/off switch for the controller.
Fig. 15
Typical Applications
V3025 Interfaced with Intel CPU ( RD and WR pulse)
Fig. 16
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V3025
V3025 Interfaced with Motorola CPU ( DS or RD pin tied to CS , and R/ W )
Fig. 17
Ordering and Package Information
Dimensions of 28-pin SOIC Package
Fig. 18
Ordering Information When ordering, please specify the complete part number. Part Number Package Delivery Form
V3025SO28B V3025SO28A
28-pin SOIC 28-pin SOIC
Tape & Reel Stick
Package Marking (first line) V3025 28SI V3025 28SI
EM Microelectronic-Marin SA cannot assume responsibility for use of any circuitry described other than circuitry entirely embodied in an EM Microelectronic-Marin SA product. EM Microelectronic-Marin SA reserves the right to change the circuitry and specifications without notice at any time. You are strongly urged to ensure that the information given has not been superseded by a more up-to-date version.
© EM Microelectronic-Marin SA, 09/04, Rev. F Copyright © 2004, EM Microelectronic-Marin SA 17 www.emmicroelectronic.com