 Many
applications require the date and time, and Real-Time Clocks provide
those functions. For example, in data storage applications, all
files have date and time attributes that are updated every time
a file is created or modified, and the RTC data must be accessed
every time that occurs.
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RTCs can be implemented in software and in ASIC logic. But maintaining
the clock can present added power management challenges. While low-power
microcontrollers and ASICs are available, they still draw much more
current than a dedicated RTC, and often cannot operate over a wide
voltage range.
A better solution is ST’s new M41T6x family of Serial RTCs.
These devices lead the way with low current and low voltage operation
and come in a tiny QFN package. |
| M41T6X Family Features |
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350nA Standby (typ) at 3.0V; |
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1.3V to 3.6V Operation - timekeeping down to 1.0V; |
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400KHz I2C Interface; |
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BCD registers for year, month, day, date, hours, minutes,
seconds, 10ths of seconds, and 100ths of seconds; |
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2 Century bits (Y2.1K compliant); |
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Automatic Leap Year adjustment; |
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Lead-free QFN16 package; |
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–40° to +85°C operating range; |
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Programmable Alarm and Interrupt; |
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Programmable Squarewave Output; and |
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Dedicated 32KHz Output. |
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| Ultra Low Standby Current |
The M41T6x family boasts typical standby currents of only 350nA
at 3.0V, which makes ST a leader in the marketplace.
These RTCs do not include battery switchover circuits, but are
targeted at applications where they are not needed. In many of
today’s applications, the entire system is often backed
up, so individual components such as the RTCs do not need backup
circuitry on chip. Capacitor backup is another example where switchover
is not required. The capacitor’s charging diode inherently
provides the switchover mechanism.
Handheld applications are a case where the RTC may run off the
system battery and also be backed up by a capacitor. And since
there is no backup circuitry, the RTC can be made smaller and
less costly, and use even lower power. Since current draw is very
important in handheld and battery operated systems, the RTC's
standby current is a critical parameter. It determines the rate
of battery consumption - how long the battery will last - as well
as the backup life when using capacitor backup. Drawing only 350nA,
users can get from minutes to months of backup time with a capacitor.
And they will not encounter the regulatory issues often associated
with batteries. |
| Small QFN16 Package |
 Today’s
handheld devices put more functions into small packages than ever
before, and when users are doing that, they want the smallest packages
available. ST’s QFN16 measures only 3mm by 3mm, and is as
small as any RTC in the industry. |
| Low Voltage Operation |
While 5V applications are still around, there is shrinking
demand for them, but there is growing demand for 3V and 3.3V solutions.
Furthermore, the next sweetspot is expected to be 1.8V. Operating
from 1.3V to 3.6V, the M41T6x family meets today’s demands,
and will meet tomorrow’s, too. Plus, they will keep time
all the way down to 1.0V. These are outstanding numbers that should
please any user.
In capacitor-backed applications (because they keep time all
the way down to 1.0V), the M41T6x series RTCs are able to use
more of the charge stored in the backup capacitor, thereby extending
the backup life even further. This means less capacitance is required
for a given backup time. For the double layer capacitors (“SuperCaps”)
often used in these applications, reducing the capacitance lowers
the cost.
Lower timekeeping voltage also means that in applications where
the system voltage often sags - such as in battery operated and
handheld devices - the timekeeping function is made more robust
because the voltage must drop to a lower level before the clock
begins to lose time. At the end of the day when a handheld unit’s
rechargeable batteries have begun to sag, the clock will still
be running, and the user will not need to reprogram it. |
| Oscillator Fail Detect |
Brown-out occurs when Vcc drops too low for reliable operation
of the circuit, but not low enough to ensure a proper power down/power
up sequence. Some registers may get corrupted thereby losing track
of the real time.
To detect this brown-out condition, the M41T6x parts include
an Oscillator Fail Detect circuit. If, due to low Vcc, the oscillator
begins to run intermittently, or stops altogether, a special filter
detects this and sets a bit which indicates this event has occurred.
The system software now has a bit it can check to confirm whether
the time is still good or has possibly been corrupted. This is
a key feature for many users, and a major selling point for these
devices. |
Oscillator Fail Detect Circuit |
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| 32KHz Output |
| The M41T62 includes a Watchdog and Alarm, along with a Programmable
Squarewave which defaults to 32KHz at power-up. The Calibration
feature allows users to get accuracies down to +/–5 seconds
per month, and the Oscillator Fail Detect circuit indicates when
the time may be corrupted (due to brown-out). 10ths and 100ths of
seconds are available for extra fine resolution. Drawing only 350nA
at 3.0V, the M41T62 is hard to beat. |
M41T62 Block Diagram |
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| M41T6x Product Selector |
| Serial
RTC Product Selector |
| Part
Number |
Data
sheet (PDF) |
Product
Page (HTM) |
Alarm IRQ |
Watchdog
Output |
Squarewave
Output |
32KHz |
Oscillator
Fail Detect |
| M41T65 |
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| M41T62 |
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| M41T60 |
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| More Information |
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