It has been mentioned earlier that the time domain oscilloscopes require a sweep generator that is linear with time for the x-axis display. The motion of spot on the screen from extreme left to extreme right is called sweep.
The generator which generates a waveform which is responsible for the movement of spot on screen horizontally is called time base generator or sweep generator. The sweep circuit along with the display gating functions is called time bases.
The linear sweep moves the spot from left to right while the movement of spot from right to left is not visible. This portion of waveform generated by time base is called flyback or retrace. During this time, the cathode ray tube is blanked.
The time base generator also controls the rate at which the spot moves, across the screen. This rate is to be adjusted from front panel control.
All the time dependent waveforms need x-axis to be calibrated as time axis. The sweep generator produces the movement of spot on screen such that it acts as a time axis or time base for the waveforms to be displayed. Hence the sweep generator is also called time base generator.
The two front panel controls which are used to control rate and duration of time base waveform are time/division and time variable control.
Note: the trigger circuit ensures that the horizontal sweep starts at the same point of the vertical input signal.
The time base requirements are:
1. Sweep time variations from 10nsec to 5 sec per division.
2. Time accuracy is better than 3%.
3. Linearity better is better than 1% across the cathode ray tube.
4. Ten times expansion in the horizontal amplifier which allows 1 nsec per division displays for very high speed transients.
5. The speed of the spot should be constant across the entire screen.
6. The spot should be invisible while tracing from right to left and should be visible only from left to right.
The basic sweep generator uses the charging characteristics of a capacitor to generate linear risetime voltages. Linearly increasing ramp which becomes zero with very short duration of time ensures that the spot is visible from left to right and invisible from right to left.
The image below shows a capacitor charged from a constant current source.
When switch S1 is closed, S2 is open and capacitor charges to produce linear ramp at the output. The sweep rate can be controlled by changing the value of capacitor or charging current.
Reaching to the maximum value of ramp voltage, the switch S2 is closed and S1 is open. Thus capacitor gets discharged through the resistance R. this is called flyback or retrace. The time t1 is called sweep time. The circuit is a sort of relaxation oscillator which generates sawtooth waveform. But this circuit has less accuracy. The bootstrap techniques allow much greater linearity but he techniques are much more costly.
During the sweep time, the spot moves from left to right. During retrace, the screen is blanked and spot comes back to its starting level but its movement from right to left is invisible.
Practically a trigger circuit is associated with the time base generator. This circuit generates a trigger pulse which activates the time base generator to produce a ramp.
Now when one cycle, sweep and retrace is completed then time base generator takes certain time to start the next cycle. This time is divided into two types as hold off time and waiting time.
Through the tigger circuit applies the pluse immediately after completion of cycle, the time base generator takes some time to start the ramp. This time is required to stabilize the flyback circuitry. This time is called hold off time.
Now when trigger pulse is generated b trigger circuit, the pulse has to cross certain reference level so as to activate the time base generator. This reference level is called trigger threshold.
Now after the end of hold off period, though circuit is ready, due to trigger threshold crossing, the pulse takes some time to activate time base generator. So time required by the triggering pulses to cross the trigger threshold is called waiting time.