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Theory of Operation—2445 Service

used to set the charging current fo r holdoff-ramp inte

grating capacitor C660. A control voltage from digital-to-
analog converter (DAC) U2234 (diagram 2) via multiplexer

U170 (diagram 4) is stored on C l 80. The stored voltage

level sets the base voltage for both Q154 and Q155 via

amplifier U165C. Transistors Q154 and Q155 form a
current-mirror w ith

nearly equal collector currents.

Transistor Q154 is a current-to-voltage converter that

provides negative feedback to U165C, setting loop gain.
Transistor Q155 acts as a constantcurrent source that

charges integrating capacitor C660, producing a linear
holdoff ramp.

A comparator circuit in U650 detects when the ramp

crosses a predefined threshold voltage (approximately
+3 V). When the threshold is reached, pin 10 of U650

(HRR) goes LO and the integrating capacitor is discharged.

A t that same time, an internal counter that keeps track
of the holdoff ramp cycles is incremented. The ramps

continue  to  be  generated  and  reset  until  the  holdoff  ramp
counter  has  counted  the  number  o f  ramp  cycles  defined
by  the  sweep-rate-dependent  holdoff  data  field  stored  in

the Display Sequencer control register. A t all sweep speeds

except  5  ns  per  division,  the  count  is  at  least  two  holdoff
ramp  cycles.  The  front-panel  variable  HOLDOFF  control
affects  holdoff  time  by  varying  the  HOLDOFF  control
voltage  to  U165C  (from  the  DAC),  changing  the  charging
rate  of  integrating capacitor C660.

When holdoff time requirements are met (determined

by the number of ramps counted), the Display Sequencer

sets the THO (trigger holdoff) signal LO. This enables both
the A Sweep hybrid (U700) and the A Trigger circuitry

in U500. The Trigger circuit begins monitoring the selected

trigger source line and, when a triggering event is detected
that meets the triggering requirements defined by the

stored control data, initiates the A Sweep and sets the TSA

(trigger status, A Sweep) line to Display Sequencer U650

LO (indicating that the A Sweep has been triggered).

As the A Sweep circuit (U700) responds to the trigger,

it sets the SGA (sweep gate A) line LO (via U980A)
indicating that an A Sweep is in progress. A fter the sweep

has run to completion, U700 sets the SGA line HI signaling

the end of sweep. The Display Sequencer then sets the THO

iine Hi, resetting the A/B Trigger hybrid U500 and A

Sweep hybrid U700 in preparation fo r the next sweep.

D ELAY GATE OPERATION. Analog Switches U850B

and U850C select the delay references for each sweep.

Depending on the display mode and point in the display

sequence, the DS control signal (U650 pin 40) routes one
of the tw o analog delay references through U850B and

U850C to the tw o sweep hybrids. The selected reference
level is compared against the changing sweep ramp voltages

to generate the delay gates that control each sweep's
functions.

A fter an A Sweep has been initiated by a trigger, a delay

gate circuit w ithin U700 compares the A Sweep ramp
voltage to the selected delay reference. When the sweep

ramp reaches the delay reference level, the DG (delay gate)

output goes LO, enabling the B trigger portion o f U500 and

B Sweep hybrid U900. Then, when B triggering occurs (for

TRIG AFT DLY mode), the A/B Trigger hybrid sets the

TGB (trigger gate B) signal LO, initiating the B Sweep. In

RUN A F T DLY mode, however, the TGB signal to U900 is

held LO, and the B Sweep is initiated at the end of the A
Sweep delay time when the A Sweep delay gate goes LO.

STATUS MONITORING. As the Display Sequencer

controls the display system in real time, it continually
monitors the trigger and sweep operations and updates the

internal trigger status register accordingly. The Micro
processor checks the contents of this register every 3.3 ms

to determine the current status of the trigger and sweep

circuitry. The Microprocessor reads the trigger status

register  by  generating  a  series  o f  trigger status strobe  (TSS)
pulses  (U650  pin  19)  to  serially  clock  the  contents  of  the
register  out to the TSO  (trigger status output)  line and  onto

the  Data  Bus  (via  Status  Buffer  U2108  on  diagram  2).  The
system  status  information  obtained  by  this  check  is  used
fo r  AUTO  LV L  triggering,  AUTO  free-run  triggering,
detecting  the  completion  of  all  the  sweeps  in  a  SGL  SEQ

display, and during instrument calibration.

INTENSITY CONTROL. The Display Sequencer con

trols the intensity fo r both sweep and readout displays.
The analog levels at pins 22 and 23 (set by the front-panel

INTENSITY and READOUT INTENSITY controls) deter

mine the basic intensity level of the displays. Two inter
nally generated DAC currents (developed by m ultiplying

the I REF current at pin 20 by two processor-generated

numbers stored internally) are added to the basic intensity
level currents to produce the display intensity seen on the

crt (see Table 3-1). The tw o DAC currents added to the

INTENSITY current are dependent on sweep speed, num

ber  o f  channels  being  displayed,  and  whether  or  not  the
X I 0  MAG  feature  is  in  use.  These  added  currents  increase
crt  beam  current  and  hold  the  display  intensity  some

what constant under the varying display conditions. The

resulting current is applied to Z-Axis A m plifier U950

(diagram 6) from the BRIGHT output o f the Display

Sequencer (pin 21).

To produce the intensified zone on the A Sweep trace

fo r A intensified by B Sweep displays, an additional current

is added to the c rt drive signal by the Z-Axis Am plifier

during the concurrence of the SGAZ and SGBZ (sweep gate
A and B z-axis) signals.

3-19