7
Subject to change without notice
Signal voltage U = 230Vrmsx2
√
2 = 651Vpp
(voltage > 160Vpp, with probe 10:1: U = 65.1Vpp),
desired display height H = min. 3.2div, max. 8div,
max. deflection coefficient D = 65.1:3.2 = 20.3V/div,
min. deflection coefficient D = 65.1:8 = 8.1V/div,
adjusted deflection coefficient D = 10V/div.
The previous examples are related to the CRT graticule reading.
The results can also be determined with the aid of the DV
cursor measurement (please note “controls and readout”).
The input voltage must not exceed 400V, independent from
the polarity.
If an AC voltage which is superimposed on a DC voltage is
applied, the maximum peak value of both voltages must not
or - 400V. So for AC voltages with a mean value of
zero volt the maximum peak to peak value is 800Vpp.
If attenuator probes with higher limits are used, the probes
limits are valid only if the oscilloscope is set to DC input
coupling.
If DC voltages are applied under AC input coupling conditions
the oscilloscope maximum input voltage value remains 400V.
The attenuator consists of a resistor in the probe and the 1M
Ω
input resistor of the oscilloscope, which are disabled by the AC
input coupling capacity when AC coupling is selected. This also
applies to DC voltages with superimposed AC voltages. It also
must be noted that due to the capacitive resistance of the AC
input coupling capacitor, the attenuation ratio depends on the
signal frequency. For sinewave signals with frequencies higher
than 40Hz this influence is negligible.
With the above listed exceptions
HAMEG
10:1 probes can be
used for DC measurements up to 600V or AC voltages (with
a mean value of zero volt) of 1200Vpp. The 100:1 probe
HZ53
allows for 1200V DC or 2400Vpp for AC.
It should be noted that its AC peak value is derated at higher
frequencies. If a normal x10 probe is used to measure high
voltages there is the risk that the compensation trimmer
bridging the attenuator series resistor will break down causing
damage to the input of the oscilloscope. However, if for
example only the residual ripple of a high voltage is to be
displayed on the oscilloscope, a normal x10 probe is sufficient.
In this case, an appropriate high voltage capacitor (approx. 22-
68nF) must be connected in series with the input tip of the
probe.
With
Y-POS.
control (input coupling to
GD
) it is possible to use
a horizontal graticule line as reference line for ground potential
before the measurement. It can lie below or above the horizon-
tal central line according to whether positive and/or negative
deviations from the ground potential are to be measured.
Total value of input voltage
The dotted line shows a voltage alternating at zero volt level.
If superimposed on a DC voltage, the addition of the positive
peak and the DC voltage results in the max. voltage (DC +
ACpeak).
Time Measurements
As a rule, most signals to be displayed are periodically repeating
processes, also called periods. The number of periods per
second is the repetition frequency. Depending on the time
base setting (TIME/DIV.-knob) indicated by the readout, one or
several signal periods or only a part of a period can be
displayed. The time coefficients are stated in ms/div, µs/div or
ns/div. The following examples are related to the CRT graticule
reading. The results can also be determined with the aid of the
∆
T and 1/
∆
T cursor measurement (please note “ controls and
readout”).
The duration of a signal period or a part of it is determined by
multiplying the relevant time (horizontal distance in div) by the
(calibrated) time coefficient displayed in the readout.
Uncalibrated, the time base speed can be reduced until a
maximum factor of 2.5 is reached. Therefore any intermediate
value is possible within the 1-2-5 sequence.
With the designations
L = displayed wave length in div of one period,
T = time in seconds for one period,
F = recurrence frequency in Hz of the signal,
Tc = time coefficient in ms, µs or ns/div and the relation
F = 1/T, the following equations can be stated:
However, these four values are not freely selectable. They
have to be within the following limits:
L
between 0.2 and 10div, if possible 4 to 10div,
T
between 10ns and 5s,
F
between 0.5Hz and 100MHz,
Tc
between 100ns/div and 500ms/div in 1-2-5 sequence
(with X-MAG. (x10) inactive), and
Tc
between 10ns/div and 50ms/div in 1-2-5 sequence
(with X-MAG. (x10) active).
Examples:
Displayed wavelength L = 7div,
set time coefficient Tc = 100ns/div,
required period T = 7x100x10
-9
= 0.7µs
required rec. freq. F = 1:(0.7x10
-6
) = 1.428MHz.
Signal period T = 1s,
set time coefficient Tc = 0.2s/div,
required wavelength L = 1:0.2 = 5div.
Displayed ripple wavelength L = 1div,
set time coefficient Tc = 10ms/div,
required ripple freq. F = 1:(1x10x10
-3
) = 100Hz.
TV-line frequency F = 15625Hz,
set time coefficient Tc = 10µs/div,
required wavelength L = 1:(15 625x10
-5
) = 6.4div.
Sine wavelength L = min. 4div, max. 10div,
Frequency F = 1kHz,
max. time coefficient Tc = 1:(4x10
3
) = 0.25ms/div,
min. time coefficient Tc = 1:(10x10
3
) = 0.1ms/div,
set time coefficient Tc = 0.2ms/div,
required wavelength L = 1:(10
3
x0.2x10
-3
) = 5div.
Type of signal voltage
