Abstract: This applicaTIon note describes how to reduce current consumpTIon when using the DS32kHz with Dallas Real-TIme Clocks (RTCs).
OverviewThis applicaTIon note is intended to answer some frequently asked questions about using the DS32kHz TCXO (temperature-compensated crystal oscillator) and Dallas Semiconductor real-time clocks (RTCs).
Using the DS32kHzThe DS32kHz has four pins that are required for operation: VCC, VBAT, GND, and 32kHz_OUT. The VCC, VBAT, and GND are power supply connections and must either be connected to a positive supply or grounded. The 32kHz_OUT signal is intended to drive the X1 input of the RTC. The X2 pin of the RTC should be allowed to float when driving the X1 input with an oscillator.
The DS32kHz ICC and IBAT specifications are measured with no output load. The input characteristics of the oscillator on a RTC will determine how much additional current the DS32kHz will consume. The additional current can significantly increase the size of the battery needed for operation.
Choosing an RTCDallas Semiconductor has a wide selection of RTCs from which to choose. Some of these devices were designed using a P-WELL process while the more recent devices have been designed using the first-generation N-WELL process. The second-generation N -WELL RTCs incorporate improvements that reduce the current consumption of the TCXO / RTC combination. The following data shows the current consumed by typical devices from each process. The data were taken at a battery voltage of 3.5V at + 25 ° C.
KEY:
Ind = Individual Currents; DS32kHz with output open, RTC with crystal attached and running.
Direct = DS32kHz driving the RTC X1 input directly.
RC = DS32kHz driving the RTC with a 1MΩ resistor in series with a 100pF capacitor to the X1 input.
Table 1. N-WELL (First Generation)
Table 2. N-WELL (Second Generation)
Table 3. P-WELL
Note the RTC in each of the aforementioned tables are different RTCs. This accounts for the difference in the clock currents when comparing the tables.
If the RTC has an oscillator-enable bit, the oscillator must be enabled. If the bit is not enabled, additional current will be drawn and the clock might not operate.
Table 4. RTC LIST
SummaryWhen using P-WELL and first-generation N-WELL RTC devices, use an RC circuit to achieve the minimum possible timekeeping current.
The second-generation N-WELL devices use only slightly more current with an RC circuit.
OverviewThis applicaTIon note is intended to answer some frequently asked questions about using the DS32kHz TCXO (temperature-compensated crystal oscillator) and Dallas Semiconductor real-time clocks (RTCs).
Using the DS32kHzThe DS32kHz has four pins that are required for operation: VCC, VBAT, GND, and 32kHz_OUT. The VCC, VBAT, and GND are power supply connections and must either be connected to a positive supply or grounded. The 32kHz_OUT signal is intended to drive the X1 input of the RTC. The X2 pin of the RTC should be allowed to float when driving the X1 input with an oscillator.
The DS32kHz ICC and IBAT specifications are measured with no output load. The input characteristics of the oscillator on a RTC will determine how much additional current the DS32kHz will consume. The additional current can significantly increase the size of the battery needed for operation.
Choosing an RTCDallas Semiconductor has a wide selection of RTCs from which to choose. Some of these devices were designed using a P-WELL process while the more recent devices have been designed using the first-generation N-WELL process. The second-generation N -WELL RTCs incorporate improvements that reduce the current consumption of the TCXO / RTC combination. The following data shows the current consumed by typical devices from each process. The data were taken at a battery voltage of 3.5V at + 25 ° C.
KEY:
Ind = Individual Currents; DS32kHz with output open, RTC with crystal attached and running.
Direct = DS32kHz driving the RTC X1 input directly.
RC = DS32kHz driving the RTC with a 1MΩ resistor in series with a 100pF capacitor to the X1 input.
Table 1. N-WELL (First Generation)
| Mode | DS32kHz IBAT (µA) | DS1306 IBAT (nA) |
| Ind | 1.60 | 518 |
| Direct | 11.9 | 386 |
| RC | 2.14 | 584 |
Table 2. N-WELL (Second Generation)
| Mode | DS32kHz IBAT (µA) | DS1337 ICC (nA) |
| Ind | 1.59 | 612 |
| Direct | 3.73 | 626 |
| RC | 2.11 | 622 |
Table 3. P-WELL
| Mode | DS32kHz IBAT (µA) | DS1202 IBAT (nA) |
| Ind | 1.63 | 625 |
| Direct | 87.1 | 3,410 |
| RC | 2.17 | 685 |
Note the RTC in each of the aforementioned tables are different RTCs. This accounts for the difference in the clock currents when comparing the tables.
If the RTC has an oscillator-enable bit, the oscillator must be enabled. If the bit is not enabled, additional current will be drawn and the clock might not operate.
Table 4. RTC LIST
| P-WELL Devices | First Generation N-WELL Devices | Second Generation N-WELL Devices |
| DS1202 | DS12885 | DS1337 |
| DS12885 | DS1302 | DS1338 |
| DS1283 | DS1305 / DS1306 | DS1339 |
| DS1284 | DS1307 | DS1672 |
| DS1384 | DS1315 | |
| DS14285 | DS1500 / DS1501 | |
| DS1384 | DS1315 | |
| DS1602 | ||
| DS1670 / DS1673 / DS1677 | ||
| DS1685 | ||
| DS1688 / DS1689 | ||
| DS17285 / DS17485 / DS17885 |
The second-generation N-WELL devices use only slightly more current with an RC circuit.
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