Abstract: This applicaTIon note explains the hardware and software differences between the Motorola MC146818A and the Dallas DS12885 Real-TIme Clocks (RTCs).
OverviewThe Motorola MC146818A is no longer in producTIon. There is no direct replacement for this part. However, systems that have been designed to use the MC146818A can be modified to operate with the Dallas Semiconductor DS12885, DS12887, DS1685, or DS1687. This applicaTIon note discusses the differences between these parts and potential issues in converting from the MC146818A to the Dallas Semiconductor Real Time Clocks. DescriptionThe MC146818A provided clock and calendar functions with 50 bytes of user RAM memory, and was designed to work with either the Motorola or Intel processor timing . These features could be made nonvolatile by providing a backup battery on the board to maintain the VDD supply. For timekeeping, the MC146818A required a number of discrete components on the PCB along with a crystal to provide an input frequency. The input frequencies could be 32.768 kHz, 1.048576 MHz, or 4.194304 MHz.
The DS12885 is designed to provide the same timekeeping functions with a total of 114 bytes of user NV RAM. To reduce the part count on the PCB, the DS12885 will accept direct connection of a 32.768 kHz crystal with no additional timing components required. The DS12885 also has a separate input for a backup battery with internal switching circuitry to avoid data corruption during a power fail condition. The DS12885 is available in either 24-pin DIP or 28-pin PLCC packages.
The DS1685 includes an enhanced feature set including: century byte; 64-bit serial number; wake-up alarm; kickstart; SMI recovery stack; 242 bytes of user NV RAM; and an auxiliary battery input. The timekeeping algorithm in the DS1685 includes leap year compensation valid up to 2100. The DS1685 is available in either 24-pin DIP or 28-pin PLCC packages.
The DS12887 and DS1687 are modules combining a RTC with a battery and crystal contained within the package, so that no external parts are required. The DS12887 includes the DS12885 while the DS1687 is built using the DS1685. The modules has the same foot print as the 600-mil DIP package, and can therefore be placed on existing boards with a minimum of board level changes required.
If replacing the MC146818A using an existing 600-mil DIP footprint is desired, then the DS12887 or DS1687 would be the preferred choice. This conversion will involve the least number of changes to the board and will work without removing the existing timing circuitry from the board . Using the DS12885 or DS1685 will require replacing the timing circuitry with a 32.768 kHz crystal attached directly to the crystal input pins. In order to make the DS12885 or DS1685 nonvolatile will also require the connection of a 3-volt battery directly to pins that have other functions on the MC146818A. Pin Compatibility There are some pin differences between the parts. Some of these may be addressed with software, while others may require PCB changes. Tables 1 and 2 gives the pin functions for the MC146818A, DS12885, DS1685, DS12887, and DS1687 in 600-mil DIP and PLCC packages respectively.
Note: The DS1687 and DS12887 are not available in PLCC packages.
Table 1. Pin Names
Functional Differences Table 2 summarizes the functional changes by pin for the DS12885 and DS12887. Table 3 has the changes for the DS1685 and DS1687. These changes will need to be comprehended and the appropriate modifications made to the board in replacing the MC146818A with any of the Dallas Semiconductor parts. Any pins not listed in Tables 2 and 3 are "No Connects".
Table 2. Functional Differences—DS12885 / 87
Table 3. Functional Differences—DS1685 / 87
Register DifferencesThe internal registers contained in memory locations 0A-0D are used to control the timekeeping, calendar, and interrupt functions of these parts. In the MC146818A DV2-DV0 were used to select the input frequency to provide a proper time base. Since the DS12885 / 87 and DS1685 / 87 use only the 32.768 kHz crystal these 3 bits are used to turn the oscillator on or off and to reset the countdown chain. A pattern of 010 is the only combination of bits that will turn the oscillator on and allow the RTC to keep time. A pattern of 11X will enable the oscillator but holds the countdown chain in reset. The next update will occur at 500 ms after a pattern of 010 is written to DV2-DV0. The VRT bit is maintained internally in the DS12885 / 87 and DS1685 / 87 and will continuously indicate the state of the backup battery voltage. This bit is read only.
Table 4 contains a list of the registers and the differences that will need to be comprehended in converting to the DS12885, DS12887, DS1685, or DS1687.
Table 4. Internal Registers
OverviewThe Motorola MC146818A is no longer in producTIon. There is no direct replacement for this part. However, systems that have been designed to use the MC146818A can be modified to operate with the Dallas Semiconductor DS12885, DS12887, DS1685, or DS1687. This applicaTIon note discusses the differences between these parts and potential issues in converting from the MC146818A to the Dallas Semiconductor Real Time Clocks. DescriptionThe MC146818A provided clock and calendar functions with 50 bytes of user RAM memory, and was designed to work with either the Motorola or Intel processor timing . These features could be made nonvolatile by providing a backup battery on the board to maintain the VDD supply. For timekeeping, the MC146818A required a number of discrete components on the PCB along with a crystal to provide an input frequency. The input frequencies could be 32.768 kHz, 1.048576 MHz, or 4.194304 MHz.
The DS12885 is designed to provide the same timekeeping functions with a total of 114 bytes of user NV RAM. To reduce the part count on the PCB, the DS12885 will accept direct connection of a 32.768 kHz crystal with no additional timing components required. The DS12885 also has a separate input for a backup battery with internal switching circuitry to avoid data corruption during a power fail condition. The DS12885 is available in either 24-pin DIP or 28-pin PLCC packages.
The DS1685 includes an enhanced feature set including: century byte; 64-bit serial number; wake-up alarm; kickstart; SMI recovery stack; 242 bytes of user NV RAM; and an auxiliary battery input. The timekeeping algorithm in the DS1685 includes leap year compensation valid up to 2100. The DS1685 is available in either 24-pin DIP or 28-pin PLCC packages.
The DS12887 and DS1687 are modules combining a RTC with a battery and crystal contained within the package, so that no external parts are required. The DS12887 includes the DS12885 while the DS1687 is built using the DS1685. The modules has the same foot print as the 600-mil DIP package, and can therefore be placed on existing boards with a minimum of board level changes required.
If replacing the MC146818A using an existing 600-mil DIP footprint is desired, then the DS12887 or DS1687 would be the preferred choice. This conversion will involve the least number of changes to the board and will work without removing the existing timing circuitry from the board . Using the DS12885 or DS1685 will require replacing the timing circuitry with a 32.768 kHz crystal attached directly to the crystal input pins. In order to make the DS12885 or DS1685 nonvolatile will also require the connection of a 3-volt battery directly to pins that have other functions on the MC146818A. Pin Compatibility There are some pin differences between the parts. Some of these may be addressed with software, while others may require PCB changes. Tables 1 and 2 gives the pin functions for the MC146818A, DS12885, DS1685, DS12887, and DS1687 in 600-mil DIP and PLCC packages respectively.
Note: The DS1687 and DS12887 are not available in PLCC packages.
Table 1. Pin Names
| Pin Number | MC146818A | DS12885 | DS1685 | DS12887 | DS1687 | |
| 24-Pin DIP | 24-Pin PLCC | |||||
| 1 | 2 | MOT | MOT | Active-Low PWR | MOT | Active-Low PWR |
| 2 | 3 | OSC1 | X1 | X1 | NC | NC |
| 3 | 4 | OSC2 | X2 | X2 | NC | NC |
| 4 | 5 | AD0 | AD0 | AD0 | AD0 | AD0 |
| 5 | 6 | AD1 | AD1 | AD1 | AD1 | AD1 |
| 6 | 7 | AD2 | AD2 | AD2 | AD2 | AD2 |
| 7 | 8 | AD3 | AD3 | AD3 | AD3 | AD3 |
| 9 | 10 | AD4 | AD4 | AD4 | AD4 | AD4 |
| 10 | 11 | AD5 | AD5 | AD5 | AD5 | AD5 |
| 10 | 12 | AD6 | AD6 | AD6 | AD6 | AD6 |
| 11 | 14 | AD7 | AD7 | AD7 | AD7 | AD7 |
| 12 | 15 | VSS | GND | GND | GND | GND |
| 13 | 16 | Active-Low CS | Active-Low CS | Active-Low CS | Active-Low CS | Active-Low CS |
| 14 | 17 | AS | AS | ALE | AS | ALE |
| 15 | 19 | R / Active-Low W | R / Active-Low W | R / Active-Low W | R / Active-Low W | R / Active-Low W |
| 16 | 20 | Active-Low STBY | Batt GND | Batt GND | NC | NC |
| 17 | twenty one | DS | DS | Active-Low RD | DS | / RD |
| 18 | twenty two | Active-Low RESET | Active-Low RESET | Active-Low KS | Active-Low RESET | Active-Low KS |
| 19 | twenty three | Active-Low IRQ | Active-Low IRQ | Active-Low IRQ | Active-Low IRQ | Active-Low IRQ |
| 20 | twenty four | CKFS | VBAT | VBAT | NC | NC |
| twenty one | 25 | CKOUT | Active-Low RCLR | Active-Low RCLR | NC | Active-Low RCLR |
| twenty two | 26 | PS | NC | VBAUX | NC | VBAUX |
| twenty three | 27 | SQW | SQW | SQW | SQW | SQW |
| twenty four | 28 | VDD | VCC | VCC | VCC | VCC |
Table 2. Functional Differences—DS12885 / 87
| Pin # | ||||
| DIP | PLCC | MC146818A | DS12885 | DS12887 |
| 1 | 2 | MOT | N / A | N / A |
| 2 | 3 | OSC1 | The MC146818A required external components along with crystals of 32.768 kHz, 1.048576 MHz, or 4.194304 MHz. The DS12885 is designed to work with a 32.768 kHz crystal connected directly to pins 2 and 3. | The DS12887 does not require an external crystal, so any components on the board designed to connect a crystal to this pin may be removed. The MC146818A would accept input frequencies of 32.768 kHz, 1.048576 MHz, or 4.194304 MHz. The DS12887 includes a 32.768 kHz crystal in the module. |
| 3 | 4 | OSC2 | ||
| 4 | 5 | AD0 | N / A | N / A |
| 5 | 6 | AD1 | N / A | N / A |
| 6 | 7 | AD2 | N / A | N / A |
| 7 | 8 | AD3 | N / A | N / A |
| 8 | 9 | AD4 | N / A | N / A |
| 9 | 10 | AD5 | N / A | N / A |
| 10 | 12 | AD6 | When accessing the clock memory, AD6 on the DS12885 / 87 needs to be low during the address strobe. It was a "don't care" on the MC146818A. | |
| 11 | 14 | AD7 | N / A | N / A |
| 12 | 15 | VSS | N / A | N / A |
| 13 | 16 | Active-Low CS | N / A | N / A |
| 14 | 17 | AS | N / A | N / A |
| 15 | 19 | R / Active-Low W | N / A | N / A |
| 16 | 20 | Active-Low STBY | The negative side of the backup battery needs to be connected to pin 16 of the DS12885. The DS12885 handles the switching to battery power internally and will disable reads and writes while in back backup mode. | This pin is a no connect on the DS12887. The DS12887 switches to an internal battery when VCC is not present and automatically disables reads and writes. |
| 17 | twenty one | DS | N / A | N / A |
| 18 | twenty two | Active-Low RESET | N / A | N / A |
| 19 | twenty three | Active-Low IRQ | N / A | N / A |
| 20 | twenty four | CKFS | Pin 20 needs to be connected to the positive side of the backup battery. | No Connect |
| twenty one | 25 | CKOUT | The user RAM will be cleared if this pin is taken low. There is an internal pull-up resistor, so this pin should be left floating and not tied high. | This pin is a no connect on the DS12887. On the DS12887A, the RCLR pin is brought out and should be treated the same as on the DS12885. |
| twenty two | 26 | PS | The MC146818A used this pin to sense the battery voltage and set the VRT bit. This function is handled internally in the DS12885 / 87, and the pin is a no connect. | |
| twenty three | 27 | SQW | N / A | N / A |
| twenty four | 28 | VDD | Any on board backup battery that was connected to pin 24 should be removed. The DS12885 is designed to have the backup battery connected to pins 16 and 20. The DS12887 has the backup battery included in the module. | |
Table 3. Functional Differences—DS1685 / 87
| Pin # | ||||
| DIP | PLCC | MC146818A | DS1685 | DS1687 |
| 1 | 2 | MOT | The Active-Low PWR pin on the DS1685 / 87 is an output designed to support system power switching as a result of a date / time alarm (wake up) or a key closure (kickstart). | |
| 2 | 3 | OSC1 | The MC146818A required external components along with crystals of 32.768 kHz, 1.048576 MHz, or 4.194304 MHz. The DS1685 is designed to work with a 32.768 kHz crystal connected directly to pins 2 and 3. | The DS1687 does not require an external crystal, so any components on the board designed to connect a crystal to this pin may be removed. The MC146818A would accept input frequencies of 32.768 kHz, 1.048576 MHz, or 4.194304 MHz. The DS1687 includes a 32.768 kHz crystal in the module. |
| 3 | 4 | OSC2 | ||
| 4 | 5 | AD0 | N / A | N / A |
| 5 | 6 | AD1 | N / A | N / A |
| 6 | 7 | AD2 | N / A | N / A |
| 7 | 8 | AD3 | N / A | N / A |
| 8 | 9 | AD4 | N / A | N / A |
| 9 | 10 | AD5 | N / A | N / A |
| 10 | 12 | AD6 | When accessing the clock memory, AD6 on the DS1685 / 87 needs to be low during the address strobe. It was a "don't care" on the MC146818A. | |
| 11 | 14 | AD7 | N / A | N / A |
| 12 | 15 | VSS | N / A | N / A |
| 13 | 16 | Active-Low CS | N / A | N / A |
| 14 | 17 | AS | N / A | N / A |
| 15 | 19 | R / Active-Low W | N / A | N / A |
| 16 | 20 | Active-Low STBY | The negative side of the backup battery needs to be connected to pin 16 of the DS1685. The DS1685 handles the switching to battery power internally and will disable reads and writes while in back backup mode. | This pin is a no connect on the DS1687. The DS1687 switches to an internal battery when VCC is not present and automatically disables reads and writes. |
| 17 | twenty one | DS | N / A | N / A |
| 18 | twenty two | Active-Low RESET | N / A | N / A |
| 19 | twenty three | IRQ | N / A | N / A |
| 20 | twenty four | CKFS | This pin needs to be connected to the positive side of the backup battery. | No Connect |
| twenty one | 25 | CKOUT | The user RAM will be cleared if this pin is taken low. There is an internal pull-up resistor, so this pin should be left floating and not tied high. | |
| twenty two | 26 | PS | The MC146818A used this pin to sense the battery voltage and set the VRT bit. This function is handled internally in the DS1685 / 87. This pin is the positive side for an auxiliary battery required for the kickstart and wake-up features. | |
| twenty three | 27 | SQW | N / A | N / A |
| twenty four | 28 | VDD | Any on board backup battery that was connected to VDD should be removed. The DS1685 is designed to have the backup battery connected to pins 16 and 20 in the DIP and pins 20 and 24 in the PLCC. The DS1687 has the backup battery included in the module. | |
Table 4 contains a list of the registers and the differences that will need to be comprehended in converting to the DS12885, DS12887, DS1685, or DS1687.
Table 4. Internal Registers
| DS12885 / 87 and DS1685 / 87 | ||||
| Register A | MSB | 7 | UIP | N / A |
| 6 | DV2 | N / A | ||
| 5 | DV1 | 1-Osc On; 0-Osc off | ||
| 4 | DV0 | Must be 0 for timekeeping | ||
| 3 | RS3 | N / A | ||
| 2 | RS2 | N / A | ||
| 1 | RS1 | N / A | ||
| LSB | 0 | RS0 | N / A | |
| Register B | MSB | 7 | SET | N / A |
| 6 | PIE | N / A | ||
| 5 | AIE | N / A | ||
| 4 | UIE | N / A | ||
| 3 | SQWE | N / A | ||
| 2 | DM | N / A | ||
| 1 | 24/12 | N / A | ||
| LSB | 0 | DSE | N / A | |
| Register C | MSB | 7 | IRQF | N / A |
| 6 | PF | N / A | ||
| 5 | AF | N / A | ||
| 4 | UF | N / A | ||
| 3 | 0 | N / A | ||
| 2 | 0 | N / A | ||
| 1 | 0 | N / A | ||
| LSB | 0 | 0 | N / A | |
| Register D | MSB | 7 | VRT | This bit is read only and should always be 1 to indicate a good internal battery voltage. |
| 6 | 0 | N / A | ||
| 5 | 0 | N / A | ||
| 4 | 0 | N / A | ||
| 3 | 0 | N / A | ||
| 2 | 0 | N / A | ||
| 1 | 0 | N / A | ||
| LSB | 0 | 0 | N / A | |
When the semiconductor diode is turned on, it is equivalent to the switch closing (circuit is turned on), and when it is turned off, it is equivalent to the switch opening (circuit cut), so the diode can be used for switching, and the commonly used model is 1N4148. Since the semiconductor diode has a unidirectional conduction characteristic, the PN junction is turned on under a positive bias, and the resistance in the on state is small, about several tens to several hundreds of ohms; in the reverse bias, it is off. The resistance is very large. Generally, the silicon diode is above 10 Μ Ω, and the bismuth tube is also several tens of kilo ohms to several hundred kilo ohms. With this feature, the diode will act as a control for the current to turn on or off in the circuit, making it an ideal electronic switch.
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