AN-1042 Datasheet, PDF(3/3 Page) Cymbet Corporation – EnerChip CC Backup Power for Epson RX-8564 Real-Time Clock

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AN-1042 Datasheet, PDF (3/3 Pages) Cymbet Corporation – EnerChip CC Backup Power for Epson RX-8564 Real-Time Clock

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AN-1042: EnerChipâ¢ CC Backup Power for Epson RX-8564 RTC

All of these features have been combined to create a backup power solution that eliminates the need for a

dedicated supply supervisory circuit, battery holder or socket, separate battery management circuitry, and a

conventional power source such as a coin cell or supercapacitor. The result is a compact, single-chip solution to

backup and bridging power. The power source - the EnerChip - is a component class, rechargeable solid state

battery that has no organic solvents or harmful chemicals that accompany coin cells and supercapacitors.

Given the low operating current of many RTCs, the EnerChip CC can provide several hours to several days of

backup time. Backup time is calculated based on the typical RTC current and the EnerChip CC battery cutoff

circuit current of 30nA (typical). The following table illustrates the amount of backup time afforded by the

EnerChip CC devices - CBC3105, CBC3112, and CBC3150 - when connected to the Epson RX-8564 RTC.

EnerChip CC

CBC3105

CBC3112

CBC3150

DFN/QFN Package Size (mm)

5 x 5 x 0.9

7 x 7 x 0.9

9 x 9 x 0.9

Backup Run Time (hours)

182

Given that the vast majority power interruptions - whether due to grid power outages in wall-powered systems

or in mobile devices during main battery recharging and replacement - are less than one day, either EnerChip

CC device can be used in most applications. Once the minimum backup run time specification is defined,

device selection can be made accordingly and in conjunction with other considerations such as package

footprint. The EnerChip CC is also configured to allow additional surface mount EnerChips to be connected to

increase backup run time.

In cases where an MCU must also be maintained in a low power state (as opposed to completely disconnected

from the circuit) during battery-backed operation, the MCU sleep current must be factored into the backup

run time equation. To maintain favorable backup run time, the designer can choose from a variety of MCUs,

some having sleep currents as low as 20nA. When using MCUs with such exceptionally low sleep currents,

the backup run time is not reduced significantly. During operation, the MCU can also be programmed to drive

the EnerChip CC ENABLE line low when EnerChip battery charging is not required. Doing so will reduce the

overhead current associated with operating the charge pump internal to the EnerChip CC.

Conclusion

Many systems utilizing RTCs require backup power supply backup in the event of main power interruption.

Conventional backup power sources are primary coin cells, rechargeable coin cells, and supercapacitors.

Traditional backup power sources have long charge times, high self-discharge, require relatively high steady

state parasitic charging current, and often require external components for charge control and discharge cutoff.

The EnerChip - with its low self-discharge, low parasitic current draw when charged, and fast recharge time - is

a superior solution to supercapacitors and coin cell batteries in backup power applications. When implemented

in systems using real-time clocks, the EnerChip CC delivers a robust backup power source with high cycle life

and integrated battery management in a low profile, compact surface mount package.

Doc AN-72-1042 Rev B

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