APPLICATION NOTE 1145

Interface a Multiplexed-Bus Real-Time Clock to a µP With Separate Address and Data Buses

Jul 17, 2002

Abstract: This application note provides general information about how to interface a real-time clock (RTC) that has a multiplexed-bus (multiplexed address and data) interface (example: DS12887) with a microcontroller that has separate address and data buses.

An IC multiplexed-bus real-time clock (RTC) is designed for use with processors that include a multiplexed data-address bus, but some designers prefer to use such "mux-bus" RTCs with processors whose data and address buses are separate (Figure 1).

Figure 1. The components shown interface a mux-bus RTC to a processor (DS2250) with separate data and address buses.
Figure 1. The components shown interface a mux-bus RTC to a processor (DS2250) with separate data and address buses.

The mux-bus RTC has four control signals. Chip Select (active-low CS) must be active when reading or writing data. Read Data strobe (active-low RD) is for data reads, Write Data strobe (active-low WR) is for data writes, and Address Strobe (ALE) latches the register address internally. The falling edge of ALE latches the register address (presented on pins AD0-AD7 of the Address/Data bus) whenever active-low RD and active-low WR are both high. You then transfer data to or from the selected clock register via AD0-AD7 by toggling active-low WR or active-low RD low while active-low CS is active.

In Figure 1, the interface between the RTC (DS1687) and an 8051-type processor (DS2250) ignores the expanded memory multiplexed address and data function provided by the processor's P0, P2 and ALE pins (not shown). Instead, external logic creates the ALE signal, and the RTC is memory-mapped into the expanded memory area.

The configuration above requires two address locations in the processor address space. When A0 is low, the clock-decode logic toggles ALE while active-low RD and active-low WR are held high. When A0 is high, the clock-decode logic holds ALE low while toggling active-low RD or active-low WR low. The address-decode logic holds active-low CS low for either state of A0, provided A1-15 matches the address to which the clock is mapped. In software, you access the clock by writing the register address to the lower address (A0 low), which is followed by a read or write to the upper address (A0 high). The associated software can be downloaded from the Maxim site. Figure 2 shows the complete schematic.

Figure 2.
For Larger Image
Figure 2.

Related Parts
DS12885 Real-Time Clocks Free Samples  
DS12887 Real-Time Clocks Free Samples  
DS12887A Real-Time Clocks Free Samples  
DS12C887 Real-Time Clocks Free Samples  
DS12C887A Real-Time Clocks Free Samples  
DS12CR887 RTCs with Constant-Voltage Trickle Charger Free Samples  
DS12R885 RTCs with Constant-Voltage Trickle Charger Free Samples  
DS12R887 RTCs with Constant-Voltage Trickle Charger  
DS1685 3V/5V Real-Time Clock Free Samples  
DS1687 3V/5V Real-Time Clock Free Samples  
DS1689 3 Volt/5 Volt Serialized Real Time Clock with NV RAM Control  
DS17285 3V/5V Real-Time Clocks Free Samples  
DS17287 3V/5V Real-Time Clocks Free Samples  
DS17485 3V/5V Real-Time Clocks Free Samples  
DS17487 3V/5V Real-Time Clocks Free Samples  
DS17885 3V/5V Real-Time Clocks Free Samples  
DS17887 3V/5V Real-Time Clocks Free Samples  
DS2250 Soft Microcontroller Module Free Samples  


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APP 1145: Jul 17, 2002
APPLICATION NOTE 1145, AN1145, AN 1145, APP1145, Appnote1145, Appnote 1145

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