APPLICATION NOTE 3816

Selecting a Backup Source for Real-Time Clocks

May 26, 2006

Abstract: Most Maxim real-time clocks (RTCs) include a supply input for a backup power source. This alternate supply source allows the RTC to maintain the current time and date while the main power source is absent. This application note discusses the various types of alternate supplies that can be used, as well as some of the criteria that a designer should consider when selecting a backup source.

Introduction

Maxim's first real-time clocks (RTCs) were designed so that a backup source, such as a primary (nonrechargeable) lithium coin cell, could be used as the backup supply. Since then, Maxim has introduced additional RTCs with built-in trickle chargers. There are changes that affect system requirements since the first RTCs were introduced, including the shift to IR reflow in manufacturing and restrictions on transportation and disposal of lithium cells. The following paragraphs discuss battery backup techniques and the advantages and limitations of commonly used backup supply sources.

Backup Supply Operation

Early Maxim RTCs had a relatively simple voltage-comparator circuit to monitor VCC and switch between the VCC and VBAT supplies. The DS1307, for example, uses a comparator and a voltage divider to switch to VBAT when VCC drops below approximately 1.25 times the voltage on VBAT. Other RTCs, such as the DS1305/DS1306, switch when VCC drops below the VBAT input voltage. When using these devices, care must be taken to ensure that the voltage on VBAT never rises high enough to cause the device to inadvertently switch over to VBAT while VCC is at the normal operating voltage. An external charging circuit must limit the maximum charging voltage to prevent such an occurrence. Newer Maxim RTCs, which are designed to allow operation whether VCC is above or below the voltage on VBAT, use an internal bandgap voltage reference to determine when VCC is too low for normal operation.

The following table lists the common supply technologies used for backup power. The table lists key parameters that affect selection. The paragraphs following the table discuss each technology and their advantages and drawbacks.

Table 1. Common Backup Supply Sources and Key Selection Criteria
Technology Operating Temperature (°C) PC Board Attachment Self-Discharge Rate Disposal/Transportation Restrictions Charging Circuit/Cycles Backup Time
Primary Lithium -30 to +80 Wave solder¹ Low High N/A Long
Capacitor -40 to +85 SMT High Low Simple/unlimited Short
Rechargeable (NiCd/NiMh) 0 to +40² Hand solder³ Medium Medium Simple/≈500 Short
Reflowable ML -20 to +60 SMT Low High Voltage 12 - > 1000 Medium4

  1. Primary lithium cells may be wave soldered as long as the cell temperature does not exceed +85°C. Cells may be placed in a holder or hand soldered after reflow (tabbed cells).
  2. Ambient temperature during charging. The allowed ambient temperature during discharge may be higher.
  3. Batteries may be placed in a holder or hand soldered after reflow (tabbed batteries).
  4. Total backup time is dependent upon the depth of discharge between each charging cycle.

Lithium Primary (BR and CR) Cells

Primary lithium coin cells are commonly used for RTC and memory backup. Lithium cells have a high energy density, thus taking up a small amount of room on a PC board. Lithium cells cannot withstand IR reflow, so the cell must either be soldered on after reflow or inserted in a holder, thus increasing cost. Self-discharge near room temperature and below is typically less than 1% per year. At temperatures above about +60°C, self-discharge quickly increases. Recent regulations limit the transportation of lithium primary cells aboard passenger aircraft. Other regulations govern disposal of the cells at end of life, in some cases placing the burden on the manufacturer.

Lithium primary cells are usually sized to power the RTC for the expected life of the product. To calculate cell life based upon the current draw of the RTC, divide the cell capacity in ampere-hours by the timekeeping current draw of the RTC. For example, the timekeeping current of the DS1307 RTC (with the square-wave output off) is specified as 500nA maximum. A BR1225 lithium primary cell is rated at 48mAh. Therefore, (0.048 / 500e) - 9 = 96,000 hours, or 4,000 days (almost 11 years). For additional information regarding calculating cell life, please refer to application note 505, Lithium Coin-Cell Batteries: Predicting an Application Lifetime.

The following is a list of links to some lithium coin-cell manufacturer web sites:
Panasonic®: OEM Batteries
SANYO®: Industrial Batteries

Capacitors

Large low-leakage capacitors, sometimes called supercaps, are sometimes used for backup. The advantages of a capacitor over primary lithium cells include the ability to IR reflow the capacitor and fewer regulations concerning shipment and disposal. However, capacitors require a charging circuit, and provide backup operation for a relatively short time. Capacity may decrease with use, especially at higher operating temperatures.

For additional information about capacitors for backup and how to calculate the backup time for a given capacitor size, please refer to application note 3517, Estimating Super Capacitor Backup Time on Trickle-Charger Real-Time Clocks. To determine backup time, please refer to the online Super Capacitor Calculator (For Trickle Charger RTCs).

The following is a list of links to some capacitor manufacturer web sites:
Panasonic: Gold Capacitors
NEC TOKIN: Super Capacitors
Kanthal Globar: Capacitors
Cooper Electronic Technologies: Supercapacitors

NiMH and NiCd Batteries

Rechargeable nickel metal hydride (NiMH) or nickel cadmium (NiCd) batteries are incompatible with the float-charging technique used in this trickle charger. Consequently, care must be taken to avoid potentially dangerous side effects when utilizing either of these battery chemistries.

Caution: Do not enable the trickle charger if using NiMH or NiCD batteries.

Charging NiMH or NiCD cells requires both control of the charge current and monitoring of the battery's temperature to prevent overcharging/internal gas formation. These batteries could be safely charged (externally), using an appropriate circuit for that specific chemistry. Then the battery should be installed in the final application as if it were a primary (nonrechargeable) battery.

NiMH and NiCD batteries have a relatively high self-discharge rate: about 10% per month for NiCd and 20% per month for NiMH at room temperature. The typical operating charging temperature range is approximately 0°C to +40°C. NiMH and NiCd batteries must be hand soldered or placed in a battery holder after the PC board has gone through reflow. Overcharging can reduce the life of the battery. Disposing of the battery at its end of life may be regulated in some regions. NiMH and NiCd battery life is limited by the number of charge/discharge cycles.

The following is a list of links to some rechargeable battery manufacturer web sites:
Panasonic: OEM Batteries
SANYO: Industrial Batteries

Lithium Secondary (ML) Cells

ML cells require a regulated-voltage-charging source. The maximum voltage must be closely regulated or permanent damage will occur, while too low a voltage results in incomplete charging. ML cells are subject to the same transportation and disposal regulations as lithium primary cells. The DS12R885/DS12R887 RTCs include a charger with the required voltage and current limits on-chip. The DS12R887 RTC integrates the ML cell in a BGA package.

One issue with secondary cells is the number of charge/discharge cycles that they can withstand during the normal service life. For ML cells, the number of charging cycles is directly related to the depth of discharge as detailed in the Manganese Lithium Rechargeable Cell Lifetime Calculator, an on-line tool for determining ML cell lifetime.

The following is a list of links to some rechargeable lithium ML coin cell manufacturer web sites:
Panasonic: OEM Batteries
SANYO: Industrial Batteries

Conclusion

No single RTC backup power source is perfect for every application. The designer must use such criteria as expected system lifetime, governmental regulations, and manufacturing requirements to select a backup supply that is best suited for the application. Using such criteria, the system designer can select a suitable RTC backup supply technology.

Panasonic is a registered trademark and registered service mark of Panasonic Corporation.

SANYO is a registered trademark of SANYO Electric Co., Ltd.



Related Parts
DS12885 Real-Time Clocks Free Samples  
DS12R885 RTCs with Constant-Voltage Trickle Charger Free Samples  
DS12R887 RTCs with Constant-Voltage Trickle Charger  
DS1302 Trickle-Charge Timekeeping Chip Free Samples  
DS1305 Serial Alarm Real-Time Clock Free Samples  
DS1306 Serial Alarm Real-Time Clock Free Samples  
DS1307 64 x 8, Serial, I²C Real-Time Clock Free Samples  
DS1308 Low-Current I²C RTC with 56-Byte NV RAM  
DS1315 Phantom Time Chip Free Samples  
DS1318 Parallel-Interface Elapsed Time Counter Free Samples  
DS1337 I²C Serial Real-Time Clock Free Samples  
DS1338 I²C RTC with 56-Byte NV RAM Free Samples  
DS1338 I²C RTC with 56-Byte NV RAM Free Samples  
DS1339 I²C Serial Real-Time Clock Free Samples  
DS1339A Low-Current, I²C, Serial Real-Time Clock Free Samples  
DS1339B Low-Current, I2C, Serial Real-Time Clock for High-ESR Crystals Free Samples  
DS1340 I²C RTC with Trickle Charger Free Samples  
DS1343 Low-Current SPI/3-Wire RTCs Free Samples  
DS1344 Low-Current SPI/3-Wire RTCs Free Samples  
DS1374 I²C, 32-Bit Binary Counter Watchdog RTC with Trickle Charger and Reset Input/Output Free Samples  
DS1390 Low-Voltage SPI/3-Wire RTCs with Trickle Charger Free Samples  
DS1391 Low-Voltage SPI/3-Wire RTCs with Trickle Charger Free Samples  
DS1392 Low-Voltage SPI/3-Wire RTCs with Trickle Charger Free Samples  
DS1393 Low-Voltage SPI/3-Wire RTCs with Trickle Charger Free Samples  
DS14285 Real-Time Clock with NV RAM Control  
DS1500 Y2K-Compliant Watchdog RTC with NV Control Free Samples  
DS1501 Y2K-Compliant Watchdog Real-Time Clocks Free Samples  
DS1558 Watchdog Clocks with NV RAM Control Free Samples  
DS1670 Portable System Controller Free Samples  
DS1672 I²C 32-Bit Binary Counter RTC Free Samples  
DS1673 Portable System Controller Free Samples  
DS1677 Portable System Controller Free Samples  
DS1678 Real-Time Event Recorder  
DS1685 3V/5V Real-Time Clock Free Samples  
DS17285 3V/5V Real-Time Clocks Free Samples  
DS17485 3V/5V Real-Time Clocks Free Samples  
DS17885 3V/5V Real-Time Clocks Free Samples  
DS3231 Extremely Accurate I²C-Integrated RTC/TCXO/Crystal Free Samples  
DS3231M ±5ppm, I2C Real-Time Clock Free Samples  
DS3232 Extremely Accurate I²C RTC with Integrated Crystal and SRAM Free Samples  
DS3232M ±5ppm, I²C Real-Time Clock with SRAM Free Samples  
DS3234 Extremely Accurate SPI Bus RTC with Integrated Crystal and SRAM Free Samples  
DS32KHZ 32.768kHz Temperature-Compensated Crystal Oscillator Free Samples  


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APP 3816: May 26, 2006
APPLICATION NOTE 3816, AN3816, AN 3816, APP3816, Appnote3816, Appnote 3816

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