Rainbow Electronics MAX6901 User Manual

V

CC

drops to less than 1.6V (typ), the MAX6901 resets

all register contents to the POR defaults (Table 2).

RESERVED Registers

Addresses/Commands 90h, 91h, 96h, and 97h are
reserved for factory testing ONLY. Do not write to these
registers. If inadvertent Writes are done to any of these
registers, cycle power to the MAX6901.

Power-Supply Considerations

For most applications, a 0.1µF capacitor from V

CC

to

GND provides adequate bypassing for the MAX6901. A
series resistor can be added to the supply line for oper-
ation in extremely harsh or noisy environments.

Timekeeping Current—Normal Operation

When I/O is high impedance (CS = low, or after each
rising-clock edge for a data output transfer), there is a
potential for increased timekeeping current (up to 100x)

if the I/O is allowed to float. If minimum timekeeping
current is desired, the microcontroller port pin should
be configured as an input with a weak pullup.
Alternatively, use a 100k

Ω or less pulldown or pullup

resistor (for microcontroller port pins with

≤1µA input

leakage).

There are similar considerations for 32KHZ if it is
placed in its high-impedance state. For lowest time-
keeping current, it should not be allowed to float. Force
it high or low, or terminate it with a pullup or pulldown
resistor.

Timekeeping Current—Battery Backup

Systems

Often times, an RTC is operated in a system with a
backup battery. A microprocessor supervisory circuit
with backup battery switchover, or other switching
arrangement, is used to switch power from V

CC

to

V

BATT

when V

CC

falls below a set threshold. Most of

these systems leave only the RTC and some SRAM to
run from V

BATT

. The microcontroller that communicates

with the RTC is powered only from V

CC

. When the

microcontroller is reset, its port pins typically become
high impedance. This essentially floats I/O, CS, and
SCLK on the MAX6901. There is a potential for
increased timekeeping current (up to x100) as V

CC

falls

through the linear region of the input gates for I/O,
SCLK, and CS. The duration of this effect depends on
the discharge rate of V

CC

. To minimize current draw

from V

BATT

in such systems, ensure that V

CC

falls

rapidly at power down. One option is a V

CC

discharge

resistor of 100k

Ω or less from V

CC

to ground. This also

ensures sufficient impedance when V

CC

is gone back

through the microcontroller’s ESD protection, to keep
I/O, SCLK, and CS from floating. Alternately, a 100k

Ω

pulldown (for microcontroller port pins with

≤1µA input

leakage) on each pin (I/O, SCLK, and CS) ensures that
timekeeping current specifications are met during the
power switchover.

MAX6901

3-Wire Serial RTC in a TDFN

______________________________________________________________________________________

15

Table 4. 32.768kHz Surface-Mount Watch Crystals

MANUFACTURER

MANUFACTURER

PART NO.

TEMP. RANGE

C

L

(pF)

+25

°C FREQUENCY

TOLERANCE (ppm)

Abracon Corporation

ABS25-32.768-12.5-B-2-T

-40°C to +85°C

12.5

±20

Caliber Electronics

AWS2A-32.768kHz,

-20°C to +70°C

12.5

±20

ECS INC International

ECS-.327-12.5-17

-10°C to +60°C

12.5

±20

Fox Electronics

FSM327

-40°C to +85°C

12.5

±20

M-tron

SX2010/ SX2020

-20°C to +75°C

12.5

±20

Raltron

RSE-32.768-12.5-C-T

-10°C to +60°C

12.5

±20

SaRonix

32S12A

-40°C to +85°C

12.5

±20

Figure 6. Typical Temperature Curve for 32.768kHz Watch
Crystal

TYPICAL TEMPERATURE CHARACTERISITICS

(k = 0.035ppm/

°C

2

, T

O

= +25

°C)

∆

f (ppm)

TEMPERATURE (

°C)

-250

-200

-150

-100

-50

0

-50 -40 -30 -20 -10

0

10

20

25

30

40

50

60

70

80

90