MULTIPLE-PHASE CLOCK SYSTEMS

Figure 4-39.—Example of a delay line oscillator. rectangular waveforms are normally used to turn such circuits on and off because the sharp leading and trailing edges make them ideal for timing purposes. The components used to accomplish this depend on the complexity of the computer. The components you will most frequently encounter in timing circuits are oscillators and multivibrators. Oscillators Oscillators are used in computer timing circuits for their output and frequency stability characteristics. The more important quality of the two for use in computers is their frequency stability. The speed of a clock is determined by the oscillator using a resistance-capacitance (RC) or inductance-capacitance (LC) network and/or crystal combination. An oscillator can use bipolar or MOS technology. Crystal-controlled oscillators are used in computers because they are stable even at extremely high frequencies. Master clocks in computers often use an oscillator with a delay line to deliver the basic clock phase and any additional clock phases. See figure 4-39. Multivibrators Three types of multivibrators are used in timing circuits. They are astable (free running), bistable (flip-flop), and monostable (one-shot) multivibrators. We have already discussed bistable flip-flops and their uses in a computer. How they are used will depend on the technology of the computer. Generally speaking, when used for timing circuits, we can say: Astable (free running) multivibrators provide the voltage pulse to trigger a one-shot multivibrator. Monostable (one-shot) multivibrators shape the pulse to be used to enable and disable circuits, logic gates, and special registers. They can be used in single- or multiple-phase systems. Bistable (flip-flops) multivibrators are used as a special register to count clock pulses from a one-shot multivibrator or an oscillator. TIMING CIRCUIT FUNCTIONS The uses of astable and monostable multivibrators depend on the complexity of the computer. The multivibrator can be used to provide the pulse and/or pulse shaper. Let’s discuss their two types of uses. They are single-phase clock systems and multiple-phase clock systems. SINGLE-PHASE CLOCK SYSTEMS. —A single-phase clock system consists of a free running multivibrator and a single-shot multivibrator. A free running multivibrator provides the pulse and the single-shot multivibrator shapes the pulse. An oscillator could also be used to provide the trigger pulse for a single-shot multivibrator. The pulse is the output of the pulse shaper, which is then used to enable and disable circuits in whatever sequence is necessary to properly execute the computer program. Refer to figure 4-40 for a simple diagram (block and timing) of a single-phase clock system. MULTIPLE-PHASE CLOCK SYSTEMS. —A multiple-phase clock system on the other hand provides multiple pulses that can be used to alternately enable and disable circuits. This permits functions involving more than one operation to be completed during a given clock cycle, or a given operation to be extended over more than one clock cycle. A multiple phase clock system can consist of an oscillator or free running flip-flop, and single- shot multivibrator combination, or a delay line oscillator and flip-flop combination. Remember a crystal-controlled oscillator will provide better Figure 4-40.—Example of a single-phase clock system. 4-23