AGILENT E4980A

Agilent E4980A
Precision LCR Meter
20 Hz to 2 MHz
Data Sheet
Fully compliant to
LXI Class C specification
Definitions
All specifications apply to the conditions of a 0 to 55 °C temperature range, unless
otherwise stated, and 30 minutes after the instrument has been turned on.
Specifications (spec.): Warranted performance. Specifications include guardbands to
account for the expected statistical performance distribution, measurement uncertainties,
and changes in performance due to environmental conditions.
Supplemental information is provided as information that is useful in operating the
instrument, but is not covered by the product warranty. This information is classified as
either typical or nominal.
Typical (typ.): Expected performance of an average unit without taking guardbands
into account.
Nominal (nom.): A general descriptive term that does not imply a level of performance.
How to Use Tables
When measurement conditions fall under multiple categories in a table, apply the best
value.
For example, basic accuracy Ab is 0.10% under the following conditions;
Measurement time mode
Test frequency
Test signal voltage
2
SHORT
125 Hz
0.3 Vrms
Basic Specifications
Measurement functions
Measurement parameters
•
•
•
•
•
•
•
•
•
Cp-D, Cp-Q, Cp-G, Cp-Rp
Cs-D, Cs-Q, Cs-Rs
Lp-D, Lp-Q, Lp-G, Lp-Rp, Lp-Rdc1
Ls-D, Ls-Q, Ls-Rs, Ls-Rdc1
R-X
Z-θd, Z-θr
G-B
Y-θd, Y-θr
Vdc-Idc1
Definitions
Cp
Cs
Lp
Ls
D
Q
G
Rp
Rs
Rdc
R
X
Z
Y
θd
θr
B
Vdc
Idc
Capacitance value measured with parallel-equivalent circuit model
Capacitance value measured with series-equivalent circuit model
Inductance value measured with parallel-equivalent circuit model
Inductance value measured with series-equivalent circuit model
Dissipation factor
Quality factor (inverse of D)
Equivalent parallel conductance measured with parallel-equivalent circuit model
Equivalent parallel resistance measured with parallel-equivalent circuit model
Equivalent series resistance measured with series-equivalent circuit model
Direct-current resistance
Resistance
Reactance
Impedance
Admittance
Phase angle of impedance/admittance (degree)
Phase angle of impedance/admittance (radian)
Susceptance
Direct-current voltage
Direct-current electricity
Deviation measurement function: Deviation from reference value and percentage of
deviation from reference value can be output as the result.
Equivalent circuits for measurement: Parallel, Series
Impedance range selection: Auto (auto range mode), manual (hold range mode)
Trigger mode: Internal trigger (INT), manual trigger (MAN), external trigger (EXT), GPIB
trigger (BUS)
1. Option E4980A-001 is required.
3
Table 1. Trigger delay time
Range
0 s - 999 s
Resolution
100 µs (0 s - 100 s)
1 ms (100 s - 999 s)
Table 2. Step delay time
Range
0 s - 999 s
Resolution
100 µs (0 s - 100 s)
1 ms (100 s - 999 s)
Measurement terminal: Four-terminal pair
Test cable length: 0 m, 1 m, 2 m, 4 m
Measurement time modes: Short mode, medium mode, long mode.
Table 3. Averaging
Range
1 - 256 measurements
Resolution
1
Test signal
Table 4. Test frequencies
Test frequencies
Resolution
Measurement accuracy
20 Hz - 2 MHz
0.01 Hz (20 Hz - 99.99 Hz)
0.1 Hz (100 Hz - 999.9 Hz)
1 Hz (1 kHz - 9.999 kHz)
10 Hz (10 kHz - 99.99 kHz)
100 Hz (100 kHz - 999.9 kHz)
1 kHz (1 MHz - 2 MHz)
± 0.01%
Table 5. Test signal modes
4
Normal
Program selected voltage or current at the measurement
terminals when they are opened or short-circuited, respectively.
Constant
Maintains selected voltage or current at the device under test
(DUT) independently of changes in impedance of DUT.
Signal level
Table 6. Test signal voltage
Range
Resolution
Accuracy
Normal
Constant1
0 Vrms - 2.0 Vrms
100 µVrms (0 Vrms - 0.2 Vrms)
200 µVrms (0.2 Vrms - 0.5 Vrms)
500 µVrms (0.5 Vrms - 1 Vrms)
1 mVrms (1 Vrms - 2 Vrms)
±(10% + 1 mVrms) Test frequency ≤ 1 MHz: spec.
Test frequency > 1 MHz: typ.
±(6% + 1 mVrms)
Test frequency ≤ 1 MHz: spec.
Test frequency > 1 MHz: typ.
Table 7. Test signal current
Range
Resolution
Accuracy
Normal
Constant1
0 Arms - 20 mArms
1 µArms (0 Arms - 2 mArms)
2 µArms (2 mArms - 5 mArms)
5 µArms (5 mArms - 10 mArms)
10 µArms (10 mArms - 20 mArms)
±(10% + 10 µArms) Test frequency ≤ 1 MHz: spec.
Test frequency > 1 MHz: typ.
±(6% + 10 µArms) Test frequency < = 1 MHz: spec.
Test frequency > 1 MHz: typ.
Output impedance: 100 Ω (nominal)
Test signal level monitor function
• Test signal voltage and test signal current can be monitored.
• Level monitor accuracy:
Table 8. Test signal voltage monitor accuracy (Vac)
Test signal voltage2
5 mVrms - 2 Vrms
Test frequency
≤ 1 MHz
> 1 MHz
Specification
± (3% of reading value + 0.5 mVrms)
± (6% of reading value + 1 mVrms)
Table 9. Test signal current monitor accuracy (lac)
Test signal current2
50 µArms - 20 mArms
Test frequency
≤ 1 MHz
> 1 MHz
Specification
± (3% of reading value + 5 µArms)
± (6% of reading value + 10 µArms)
1. When auto level control function is on.
2. This is not an output value but rather a displayed
test signal level.
5
Measurement display ranges
Table 10 shows the range of measured value that can be displayed on the screen.
For the effective measurement ranges, refer to Figure 1. impedance measurement
accuracy example .
Table 10. Allowable display ranges for measured values
Parameter
Measurement display range
Cs, Cp
± 1.000000 aF to 999.9999 EF
Ls, Lp
± 1.000000 aH to 999.9999 EH
D
± 0.000001 to 9.999999
Q
± 0.01 to 99999.99
R, Rs, Rp,
X, Z, Rdc
± 1.000000 aΩ to 999.9999 EΩ
G, B, Y
± 1.000000 aS to 999.9999 ES
Vdc
± 1.000000 aV to 999.9999 EV
Idc
± 1.000000 aA to 999.9999 EA
θr
± 1.000000 arad to 3.141593 rad
θd
± 0.0001 deg to 180.0000 deg
∆%
± 0.0001 % to 999.9999 %
a: 1 x 10-18, E: 1 x 1018
6
Absolute measurement accuracy
The following equations are used to calculate absolute accuracy.
Absolute accuracy Aa of |Z|, |Y|, L, C, R, X, G, B (L, C, X, and B accuracies apply
when Dx ≤ 0.1, R and G accuracies apply when Qx ≤ 0.1 )
Equation 1.
Aa
Ae
Acal
Aa = Ae + Acal
Absolute accuracy (% of reading value)
Relative accuracy (% of reading value)
Calibration accuracy (%)
where G accuracy is applied only to G-B measurements.
D accuracy (when Dx ≤ 0.1)
Equation 2.
Dx
De
θcal
De + θcal
Measured D value
Relative accuracy of D
Calibration accuracy of θ (radian)
Q accuracy (When Qx × Da < 1)
Equation 3.
Qx
Da
2 × Da)
± (Qx
±
(1 Qx × Da)
Measured Q value
Absolute accuracy of D
θ accuracy
Equation 4.
θe
θcal
θe + θcal
Relative accuracy of θ (degree)
Calibration accuracy of θ (degree)
7
G accuracy (when Dx ≤ 0.1)
Equation 5.
Dx
Bx
Da
f
Cx
Lx
Bx + Da (S)
Bx = 2πfCx =
1
2πfLx
Measured D value
Measured B value (S)
Absolute accuracy of D
Test frequency (Hz)
Measured C value (F)
Measured L value (H)
where the accuracy of G is applied to Cp-G measurements.
Absolute accuracy of Rp (when Dx ≤ 0.1)
Equation 6.
Rpx
Dx
Da
± Rpx±× Da
Dx Da
(Ω)
Measured Rp value (Ω)
Measured D value
Absolute accuracy of D
Absolute accuracy of Rs (when Dx ≤ 0.1)
Equation 7.
Dx
Xx
Da
f
Cx
Lx
8
Xx × Da
(Ω)
1
Xx =
= 2πfLx
2πfCx
Measured D value
Measured X value (Ω)
Absolute accuracy of D
Test frequency (Hz)
Measured C value (F)
Measured L value (H)
Relative accuracy
Relative accuracy includes stability, temperature coefficient, linearity, repeatability, and
calibration interpolation error. Relative accuracy is specified when all of the following
conditions are satisfied:
• Warm-up time: 30 minutes
• Test cable length: 0 m, 1 m, 2 m, or 4 m (Agilent 16047A/B/D/E)
• A “Signal Source Overload” warning does not appear.
When the test signal current exceeds a value in table 11 below, a “Signal
Source Overload” warning appears.
Table 11.
Test signal voltage
≤ 2 Vrms
> 2 Vrms
Test frequency
–
≤ 1 MHz
> 1 MHz
Vac [V]
Fm [Hz]
L_cable [m]
Condition1
–
the smaller value of either 110 mA or
130 mA - 0.0015 × Vac × (Fm / 1 MHz) × (L_cable + 0.5)
70 mA - 0.0015 × Vac × (Fm / 1 MHz) × (L_cable + 0.5)
Test signal voltage
Test frequency
Cable length
• OPEN and SHORT corrections have been performed.
• Bias current isolation: Off
• The DC bias current does not exceed a set value within each range of the DC
bias current
• The optimum impedance range is selected by matching the impedance of DUT to the
effective measuring range.
• Under an AC magnetic field, the following equation is applied to the measurement
accuracy.
A x ( 1 + B x ( 2 + 0.5 / Vs))
Where
A: Absolute accuracy
B: Magnetic flux density [Gauss]
Vs: Test signal voltage level [Volts]
|Z|, |Y|, L, C, R, X, G, and B accuracy (L, C, X, and B accuracies apply when
Dx ≤ 0.1, R and G accuracies apply Qx ≤ 0.1)
Relative accuracy Ae is given as:
Equation 8.
Zm
Ab
Zs
Yo
Kt
Ae = [Ab + Zs /|Zm| × 100 + Yo × |Zm| × 100 ] × Kt
Impedance of DUT
Basic accuracy
Short offset
Open offset
Temperature coefficient
D accuracy
D accuracy De is given as
• when Dx ≤ 0.1
Equation 9.
Dx
Ae
1. When the calculation result is a negative value,
0 A is applied.
De = ±Ae/100
Measured D value
Relative accuracies of |Z|, |Y|, L, C, R, X, G, and B
• when Dx > 0.1, multiply De by (1 + Dx)
9
Q accuracy (when Q x De < 1)
Q accuracy Qe is given as:
Equation 10.
Qx
De
Qe = ±
(Qx2 × De)
±
(1 Qx × De)
Measured Q value
Relative D accuracy
θ accuracy
θ accuracy θe is given as:
Equation 11.
θe = 180 × Ae
π × 100
Ae
(deg)
Relative accuracies of |Z|, |Y|, L, C, R, X, G, and B
G accuracy (when Dx ≤ 0.1)
G accuracy Ge is given as:
Equation 12.
Ge
Dx
Bx
De
f
Cx
Lx
Ge = Bx × De
(S)
1
Bx = 2πfCx =
2πfLx
Relative G accuracy
Measured D value
Measured B value
Relative D accuracy
Test frequency
Measured C value (F)
Measured L value (H)
Rp accuracy (when Dx ≤ 0.1)
Rp accuracy Rpe is given as:
Equation 13.
Rpe
Rpx
Dx
De
Rpe = ±
Rpx × De
±
Dx De
Relative Rp accuracy
Measured Rp value (Ω)
Measured D value
Relative D accuracy
Rs accuracy (when Dx ≤ 0.1)
Rs accuracy Rse is given as:
Equation 14.
Rse
Dx
Xx
De
f
Cx
Lx
10
Rse = Xx × De
(Ω)
1
Xx =
= 2πfLx
2πfCx
Relative Rs accuracy
Measured D value
Measured X value (Ω)
Relative D accuracy
Test frequency (Hz)
Measured C value (F)
Measured L value (H)
(Ω)
Example of C-D accuracy calculation
Measurement conditions
Test Frequency:
Measured C value:
Test signal voltage:
Measurement time mode:
Measurement temperature:
1 kHz
100 nF
1 Vrms
Medium
23 °C
Ab = 0.05%
|Zm| = 1 / (2π × 1 × 103 × 100 × 10-9) = 1590 Ω
Zs = 0.6 mΩ × (1 + 0.400/1) × (1 + √(1000/1000) = 1.68 mΩ
Yo = 0.5 nS × (1 + 0.100/1) × (1 + √(100/1000) = 0.72 nS
C accuracy: Ae = [0.05 + 1.68 m/1590 × 100 + 0.72 n × 1590 × 100] × 1 = 0.05%
D accuracy: De = 0.05/100 = 0.0005
Basic accuracy
Basic accuracy Ab is given below.
Table 12. Measurement time mode = SHORT
Test signal voltage
Test
frequency [Hz]
20 - 125
125 - 1 M
1M-2M
5 mVrms 50 mVrms
(0.6%) ×
(50 mVrms/Vs)
(0.2%) ×
(50 mVrms/Vs)
(0.4%) ×
(50 mVrms/Vs)
50 mVrms 0.3 Vrms
0.60%
0.3 Vrms 1 Vrms
0.30%
1 Vrms 10 Vrms
0.30%
10 Vrms 20 Vrms
0.30%
0.20%
0.10%
0.15%
0.15%
0.40%
0.20%
0.30%
0.30%
Table 13. Measurement time mode = MED, LONG
Test signal voltage
Test
frequency [Hz]
20 - 100
100 - 1 M
1M-2M
Vs [Vrms]
5 mVrms 50 mVrms
(0.25%) ×
(30 mVrms/Vs)
(0.1%) ×
(30 mVrms/Vs)
(0.2%) ×
(30 mVrms/Vs)
50 mVrms 0.3 Vrms
0.25%
0.3 Vrms 1 Vrms
0.10%
1 Vrms 10 Vrms
0.15%
10 Vrms 20 Vrms
0.15%
0.10%
0.05%
0.10%
0.15%
0.20%
0.10%
0.20%
0.30%
Test signal voltage
11
Effect by impedance of DUT
Table 14. For impedance of DUT below 30 Ω, the following value is added.
Test
frequency [Hz]
20 - 1 M
1M-2M
Impedance of DUT
1.08 Ω ≤ |Zx| < 30 Ω
|Zx| < 1.08 Ω
0.05%
0.10%
0.10%
0.20%
Table 15. For impedance of DUT over 9.2 k Ω, the following value is added.
Test
frequency [Hz]
10 k - 100 k
100 k - 1 M
1M-2M
Impedance of DUT
9.2 kΩ < |Zx| ≤ 92 kΩ
92 kΩ < |Zx|
0%
0.05%
0.05%
0.05%
0.10%
0.10%
Effect of cable extension
When the cable is extended, the following element is added per one meter.
0.015 % × (Fm/1 MHz)2 × (L_cable)2
Fm [Hz]
L_cable [m]
12
Test Frequency
Cable length
Short offset Zs
Table 16. Impedance of DUT > 1.08 Ω
Test
frequency [Hz]
20 - 2 M
Measurement time mode
SHORT
MED, LONG
2.5 mΩ × (1 + 0.400/Vs) ×
0.6 mΩ × (1 + 0.400/Vs) ×
(1 + √(1000/Fm))
(1 + √(1000/Fm))
Table 17. Impedance of DUT ≤ 1.08 Ω
Test
frequency [Hz]
20 - 2 M
Vs [Vrms]
Fm [Hz]
Measurement time mode
SHORT
MED, LONG
1 mΩ × (1 + 1/Vs) ×
0.2 mΩ × (1 + 1/Vs) ×
(1 + √(1000/Fm))
(1 + √(1000/Fm))
Test signal voltage
Test frequency
Effect of cable extension (Short offset)
Table 18. When the cable is extended, the following value is added to Zs
(independent of the measurement time mode).
Test
frequency [Hz]
0m
20 - 1 M
1M-2M
0
0
Cable length
1m
0.25 mΩ
1 mΩ
2m
4m
0.5 mΩ
2 mΩ
1 mΩ
4 mΩ
Open offset Yo
Table 19. Test signal voltage ≤ 2.0 Vrms
Test
frequency [Hz]
20 - 100 k
100 k - 1 M
1M-2M
Measurement time mode
SHORT
MED, LONG
2 nS × (1 + 0.100/Vs) ×
0.5 nS × (1 + 0.100/Vs) ×
(1 + √(100/Fm))
(1 + √(100/Fm))
20 nS × (1 + 0.100/Vs)
5 nS × (1 + 0.100/Vs)
40 nS × (1 + 0.100/Vs)
10 nS × (1 + 0.100/Vs)
Table 20. Test signal voltage > 2.0 Vrms
Test
frequency [Hz]
20 - 100 k
100 k - 1 M
1M-2M
Note
The Open Offset may become three times
greater in the ranges of 40 to 70 kHz and 80 to
100 kHz due to residual response.
Vs [Vrms]
Fm [Hz]
Measurement time mode
SHORT
MED, LONG
2 nS × (1 + 2/Vs) ×
0.5 nS × (1 + 2/Vs) ×
(1 + √(100/Fm))
(1 + √(100/Fm))
20 nS × (1 + 2/Vs)
5 nS × (1 + 2/Vs)
40 nS × (1 + 2/Vs)
10 nS × (1 + 2/Vs)
Test signal voltage
Test frequency
13
Effect of cable length
Table 21. When the cable is extended, multiply Yo by the following factor.
Test
frequency [Hz]
100 - 100 k
100 k - 1 M
1M-2M
Fm [Hz]
0m
1
1
1
Cable length
1m
2m
1 + 5 × Fm/1 MHz
1 + 10 × Fm/1 MHz
1 + 0.5 × Fm/1 MHz
1 + 1 × Fm/1 MHz
1 + 1 × Fm/1 MHz
1 + 2 × Fm/1 MHz
Test frequency
Temperature factor Kt
Table 22. The temperature factor Kt is given below.
Temperature [°C]
0 - 18
18 - 28
28 - 55
14
Kt
4
1
4
4m
1 + 20 × Fm/1 MHz
1 + 2 × Fm/1 MHz
1 + 4 × Fm/1 MHz
Calibration accuracy Acal
Calibration accuracy Acal is given below.
For impedance of DUT on the boundary line, apply the smaller value.
Table 23. Impedance range = 0.1, 1, 10 Ω
|Z| [%]
20 - 1 k
0.03
θ [radian] 1 × 10-4
1 k - 10 k
0.05
2 × 10-4
Test frequency [Hz]
10 k -100 k
100 k - 300 k
0.05
0.05 +
5 × 10-5 Fm
-4
3 × 10
3 × 10-4 +
2 × 10-7 Fm
300 k - 1 M
0.05 +
5 × 10-5 Fm
3 × 10-4 +
2 × 10-7 Fm
1M-2M
0.1 +
1 × 10-4 Fm
6 × 10-4 +
4 × 10-7 Fm
300 k - 1 M
0.05 +
5 × 10-5 Fm
3 × 10-4
1M-2M
0.1 +
1 × 10-4 Fm
6 × 10-4
300 k - 1 M
0.05
3 × 10-4
1M-2M
0.1
6 × 10-4
Table 24. Impedance range = 100 Ω
|Z| [%]
20 - 1 k
0.03
1 k - 10 k
0.05
θ [radian] 1 × 10-4 2 × 10-4
Test frequency [Hz]
10 k -100 k
100 k - 300 k
0.05
0.05 +
5 × 10-5 Fm
3 × 10-4
3 × 10-4
Table 25. Impedance range = 300, 1 kΩ
20 - 1 k
|Z| [%] 0.03
θ [radian] 1 × 10-4
1 k - 10 k
0.03
1 × 10-4
Test frequency [Hz]
10 k -100 k
100 k - 300 k
0.05
0.05
3 × 10-4
3 × 10-4
Table 26. Impedance range = 3 k, 10 kΩ
20 - 1 k
|Z| [%] 0.03 +
1 × 10-4 Fm
θ [radian] (100 +
2.5 Fm) × 10-6
Test frequency [Hz]
1 k - 10 k
10 k -100 k
100 k - 300 k
0.03 +
0.03 +
0.03 +
1 × 10-4 Fm
1 × 10-4 Fm
1 × 10-4 Fm
(100 +
(100 +
(100 +
2.5 Fm) × 10-6 2.5 Fm) × 10-6 2.5 Fm) × 10-6
300 k - 1 M
0.03 +
1 × 10-4 Fm
(100 +
2.5 Fm) × 10-6
1M-2M
0.06 +
2 × 10-4 Fm
(200 +
5 Fm) × 10-6
Table 27. Impedance range = 30 k, 100 kΩ
20 - 1 k
|Z| [%] 0.03 +
1 × 10-3 Fm
θ [radian] (100 +
20 Fm) × 10-6
Test frequency [Hz]
1 k - 10 k
10 k -100 k
100 k - 300 k
0.03 +
0.03 +
0.03 +
1 × 10-3 Fm 1 × 10-3 Fm
1 × 10-3 Fm
(100 +
(100 +
(100 +
20 Fm) × 10-6 20 Fm) × 10-6 20 Fm) × 10-6
300 k - 1 M 1 M - 2 M
0.03 +
0.06 +
1 × 10-4 Fm 2 × 10-4 Fm
(100 +
(200 +
2.5 Fm) × 10-6 5 Fm) × 10-6
Fm[kHz] Test frequency
15
Measurement accuracy
The impedance measurement calculation example below is the result of absolute
measurement accuracy.
1p
10
1n
F
pF
1G
H
1M
10
0f
F
10
10n
100M
100n
10M
H 10
f
0k
10
F
kH
10
1f
F
H
1k
10
0a
F
0H
10
H
0p
10.0%
10
1n
1.0%
1H
F
F
0.3%
H
0m
10
10
1μ
nF
1M
0.1%
10
10μ
0n
F
100k
H
1m
1μ
F
10k
H
[Ω]
[S]
100μ
0μ
10
10
1k
μF
C
1m
μH
10
10
0μ
10m
100
100m
10
F
0.1%
H
1μ
1m
F
H
10
0n
10
m
1
H
m
10
F
1
0.3%
nH
10
10
0m
10
100m
F
1.0%
H
100
10m
1n
1F
10.0%
H
0p
10
10
1m
20
100
1k
10k
100k
1M 2M
Frequency [ Hz ]
Figure 1. Impedance measurement accuracy (Test signal voltage = 1 Vrms, cable length=0 m,
measurement time mode = MED)
16
Compensation function
Table 28. The E4980A provides three types of compensation functions:
OPEN compensation, SHORT compensation, and LOAD compensation.
Type of compensation
Description
OPEN compensation
Compensates errors caused by the stray admittance (C, G)
of the test fixture.
Compensates errors caused by the residual impedance (L, R)
of the test fixture.
Compensates errors between the actual measured value
and a known standard value under the measurement conditions
desired by the user.
SHORT compensation
LOAD compensation
List sweep
Points: There is a maximum of 201 points.
First sweep parameter (primary parameter): Test frequency, test signal voltage, test
signal current, test signal voltage of DC bias signal, test signal current of DC bias
signal, DC source voltage.
Note
A parameter selected for one of the two
parameters cannot be selected for the other
parameter. It is not possible to set up a
combination of test signal voltage and test
signal current or one of test signal voltage of
DC bias signal and test signal current of DC bias.
The secondary parameter can be set only with
SCPI commands.
Second sweep parameter (secondary parameter): None, impedance range, test
frequency, test signal voltage, test signal current, test signal voltage of DC bias signal,
test signal current of DC bias signal, DC source voltage
Trigger mode
Sequential mode: When the E4980A is triggered once, the device is measured at all
sweep points. /EOM/INDEX is output only once.
Step mode: The sweep point is incremented each time the E4980A is triggered.
/EOM/INDEX is output at each point, but the result of the comparator function of the
list sweep is available only after the last /EOM is output.
17
Comparator function of list sweep: The comparator function enables setting one pair of
lower and upper limits for each measurement point.
You can select from: Judge with the first sweep parameter/Judge with the second
parameter/Not used for each pair of limits.
Time stamp function: In the sequential mode, it is possible to record the measurement
starting time at each measurement point by defining the time when FW detects a trigger
as 0 and obtain it later with the SCPI command.
Comparator function
Bin sort: The primary parameter can be sorted into 9 BINs, OUT_OF_BINS, AUX_BIN,
and LOW_C_REJECT. The secondary parameter can be sorted into HIGH, IN, and LOW.
The sequential mode and tolerance mode can be selected as the sorting mode.
Limit setup: Absolute value, deviation value, and % deviation value can be used for setup.
BIN count: Countable from 0 to 999999.
DC bias signal
Table 29. Test signal voltage
Range
Resolution
Accuracy
0 V to +2 V
0 V / 1.5 V / 2 V only
0.1% + 2 mV (23 °C ± 5 °C)
(0.1% + 2 mV) × 4
(0 to 18 °C or 28 to 55 °C)
Output impedance: 100 Ω (nominal)
Measurement assistance functions
Data buffer function: Up to 201 measurement results can be read out in a batch.
Save/Recall function:
• Up to 10 setup conditions can be written to/read from the built-in non-volatile memory.
• Up to 10 setup conditions can be written to/read from the USB memory.
• Auto recall function can be performed when the setting conditions are written to
Register 10 of the USB memory.
Key lock function: The front panel keys can be locked.
Note
The following USB memory can be used.
Complies with USB 1.1; mass storage class,
FAT16/FAT32 format; maximum consumption
current is below 500 mA.
Recommended USB memory: 512 MB USB
Flash memory (Agilent PN 1819-0195).
Use the recommended USB memory device
exclusively for the E4980A, otherwise,
previously saved data may be cleared. If you
use a USB memory other than the recommended device, data may not be saved or recalled
normally.
Agilent Technologies will NOT be responsible
for data loss in the USB memory caused by
using the E4980A.
18
GPIB: 24-pin D-Sub (Type D-24), female; complies with IEEE488.1, 2 and SCPI.
USB host port: Universal serial bus jack, type-A (4 contact positions, contact 1 is on
your left), female (for connection to USB memory only).
USB interface port: Universal serial bus jack, type mini-B (4 contact positions); complies
with USBTMC-USB488 and USB 2.0; female; for connection to the external controller.
USBTMC: Abbreviation for USB Test & Measurement Class
LAN: 10/100 BaseT Ethernet, 8 pins (two speed options)
LXI Compliance: Class C (only applies to units with firmware revision A.02.00 or later)
Options
Note
Option xxx is described as E4980A-xxx in the
order information
The following options are available for the E4980A LCR Meter.
Option 001 (Power and DC bias enhancement)
Increases test signal voltage and adds the variable DC bias voltage function.
Measurement parameters
The following parameters can be used.
• Lp-Rdc
• Ls-Rdc
• Vdc-Idc
where
Rdc
Vdc
Idc
Direct-current resistance (DCR)
Direct-current voltage
Direct-current electricity
Test signal
Signal level
Table 30. Test signal voltage
Range
0 Vrms to 20 Vrms (test frequency ≤ 1 MHz)
0 Vrms to 15 Vrms (test frequency > 1 MHz)
100 µVrms (0 Vrms - 0.2 Vrms)
200 µVrms (0.2 Vrms - 0.5 Vrms)
500 µVrms (0.5 Vrms - 1 Vrms)
1 mVrms (1 Vrms - 2 Vrms)
2 mVrms (2 Vrms - 5 Vrms)
5 mVrms (5 Vrms - 10 Vrms)
10 mVrms (10 Vrms - 20 Vrms)
Resolution
Setup accuracy
normal
±(10% + 1 mVrms) (test signal voltage ≤ 2 Vrms)
(test frequency ≤ 1 MHz : spec., test frequency > 1 MHz : typ.)
±(10% + 10 mVrms) (Test frequency ≤ 300 kHz,
test signal voltage > 2 Vrms) (spec.)
±(15% + 20 mVrms) (test frequency > 300 kHz,
test signal voltage > 2 Vrms) (test frequency ≤ 1 MHz : spec.,
test frequency > 1 MHz : typ.)
Constant1
±(6% + 1 mVrms) (test signal voltage ≤ 2 Vrms)
(test frequency ≤ 1 MHz : spec. , test frequency > 1 MHz : typ.)
±(6% + 10 mVrms) (test frequency ≤ 300 kHz,
test signal voltage > 2 Vrms) (spec.)
±(12% + 20 mVrms) (test frequency > 300 kHz,
test signal voltage > 2 Vrms) (test frequency ≤ 1 MHz : spec.,
test frequency > 1 MHz : typ.)
1. When auto level control function is on.
19
Table 31. Test signal current
Range
Resolution
Setup accuracy
0 Arms - 100 mArms
1 µArms (0 Arms - 2 mArms)
2 µArms (2 mArms - 5 mArms)
5 µArms (5 mArms - 10 mArms)
10 µArms (10 mArms - 20 mArms)
20 µArms (20 mArms - 50 mArms)
50 µArms (50 mArms - 100 mArms)
normal
±(10% + 10 µArms) (test signal voltage ≤ 20 mArms)
(test frequency ≤ 1 MHz : spec., test frequency > 1 MHz : typ.)
±(10% + 100 µArms) (test frequency ≤ 300 kHz,
test signal current > 20 mArms) (spec.)
±(15% + 200 µArms) (test frequency > 300 kHz,
test signal voltage > 20 mArms) (test frequency ≤ 1 MHz : spec.,
test frequency > 1 MHz : typ.)
Constant1
±(6% + 10 µArms) (test signal voltage ≤ 20 mArms)
(test frequency ≤ 1 MHz : spec. , test frequency > 1 MHz : typ.)
±(6% + 100 µArms) (test frequency ≤ 300 kHz,
test signal voltage > 20 mArms) (spec.)
±(12% + 200 µArms) (test frequency > 300 kHz,
test signal voltage > 20 mArms) (test frequency ≤ 1 MHz : spec.,
test frequency > 1 MHz : typ.)
Test signal level monitor function
• Test signal voltage and test signal current can be monitored.
• Level monitor accuracy:
Table 32. Test signal voltage monitor accuracy (Vac)
Test signal voltage2
5 mVrms to 2 Vrms
> 2 Vrms
Test frequency
≤ 1 MHz
> 1MHz
≤ 300 kHz
> 300 kHz
Specification
±(3% of reading value + 0.5 mVrms)
±(6% of reading value + 1 mVrms)
±(3% of reading value + 5 mVrms)
±(6% of reading value + 10 mVrms)3
Table 33. Test signal current monitor accuracy (Iac)
Test signal current2
Test frequency
Specification
50 µArms to 20 mArms
≤ 1 MHz
> 1MHz
±(3% of reading value + 5 µArms)
±(6% of reading value + 10 µArms)
> 20 mArms
≤ 300 kHz
> 300 kHz
±(3% of reading value + 50 µArms)
±(6% of reading value + 100 µArms)
1. When auto level control function is on.
2. This is not an output value but a displayed test signal level
3. Typ. when test frequency is > 1 MHz with test signal voltage > 10 Vrms.
20
DC bias signal
Table 34. Test signal voltage
Range
Resolution
Accuracy
test signal voltage ≤ 2 Vrms
test signal voltage > 2 Vrms
–40 V to +40 V
Setup resolution: 100 µV, effective
resolution: 330 µV ±(0 V - 5 V)
1 mV ±(5 V - 10 V)
2 mV ±(10 V - 20 V)
5 mV ±(20 V - 40 V)
0.1% + 2 mV (23 °C ± 5 °C)
(0.1% + 2 mV) x 4
(0 to 18 °C or 28 to 55 °C)
0.1 % + 4 mV (23 °C ± 5 °C)
(0.1% + 4 mV) x 4
(0 to 18 °C or 28 to 55 °C)
Table 35. Test signal current
Range
Resolution
–100 mA - 100 mA
Setup resolution: 1 µA, effective
resolution: 3.3 µA ±(0 A - 50 mA)
10 µA ±(50 mA - 100 mA)
DC bias voltage level monitor Vdc
(0.5% of reading value + 60 mV) × Kt
When using Vdc-Idc measurement: (spec.)
When using level monitor: (typ.)
Kt
Temperature coefficient
DC bias current level monitor Idc
(A [%] of the measurement value + B [A]) × Kt
When using Vdc-Idc measurement: (spec.)
When using level monitor: (typ.)
A [%]
When the measurement time mode is SHORT: 2%
When the measurement time mode is MED or LONG: 1%
B [A]
given below
Kt
Temperature coefficient
When the measurement mode is SHORT, double the following value.
21
Table 36. Test signal voltage ≤ 0.2 Vrms (measurement time mode = MED, LONG)
DC bias
current range
20 µA
200 µA
2 mA
20 mA
100 mA
Impedance range [Ω]
100
300, 1 k
30 µA
3 µA
30 µA
3 µA
30 µA
3 µA
30 µA
30 µA
150 µA
150 µA
< 100
150 µA
150 µA
150 µA
150 µA
150 µA
3 k, 10 k
300 nA
300 nA
3 µA
30 µA
150 µA
30k, 100 k
45 nA
300 nA
3 µA
30 µA
150 µA
10k, 30 k
300 nA
300 nA
3 µA
30 µA
150 µA
100 k
45 nA
300 nA
3 µA
30 µA
150 µA
Table 37. 0.2 Vrms < test signal voltage ≤ 2 Vrms
(measurement time mode = MED, LONG)
DC bias
current range
20 µA
200 µA
2 mA
20 mA
100 mA
Impedance range [Ω]
100, 300
1k, 3 k
30 µA
3 µA
30 µA
3 µA
30 µA
3 µA
30 µA
30 µA
150 µA
150 µA
< 100
150 µA
150 µA
150 µA
150 µA
150 µA
Table 38. Test signal voltage > 2 Vrms (measurement time mode = MED, LONG)
DC bias
current range
20 µA
200 µA
2 mA
20 mA
100 mA
Impedance range [Ω]
1 k, 3 k
10k, 30 k
30 µA
3 µA
30 µA
3 µA
30 µA
3 µA
30 µA
30 µA
150 µA
150 µA
≤ 300
150 µA
150 µA
150 µA
150 µA
150 µA
Table 39. Input impedance (nominal)
Input
impedance
Conditions
0Ω
Other than conditions below.
20 Ω
Test signal voltage ≤ 0.2 Vrms, Impedance range ≥ 3 k Ω,
DC bias current range ≤ 200 µA
Test signal voltage ≤ 2 Vrms, Impedance range ≥ 10 kΩ,
DC bias current range ≤ 200 µA
Test signal voltage > 2 Vrms, Impedance range = 100 kΩ,
DC bias current range ≤ 200 µA
DC source signal
Table 40. Test signal voltage
Range
Resolution
Accuracy
–10 V to 10 V
1 mV
0.1% + 3 mV (23 °C ± 5 °C)
(0.1% + 3 mV) x 4
(0 to 18 °C or 28 to 55 °C)
Table 41. Test signal current
Range
Output impedance
100 Ω (nominal)
22
–45 mA to 45 mA (nominal)
100 k
300 nA
300 nA
3 µA
30 µA
150 µA
DC resistance (Rdc) accuracy
Absolute measurement accuracy Aa
Absolute measurement accuracy Aa is given as
Equation 15.
Aa = Ae + Acal
Aa Absolute accuracy (% of reading value)
Ae Relative accuracy (% of reading value)
Acal Calibration accuracy
Relative measurement accuracy Ae
Relative measurement accuracy Ae is given as
Equation 16.
Rm
Ab
Rs
Go
Kt
Ae = [Ab + (Rs /|Rm|+ Go × |Rm|) × 100 ] × Kt
Measurement value
Basic accuracy
Short offset [Ω]
Open offset [S]
Temperature coefficient
Calibration accuracy Acal
Calibration accuracy Acal is 0.03%.
Basic accuracy Ab
Table 42. Basic accuracy Ab is given below.
Measurement
time mode
SHORT
MED
Test signal voltage
≤ 2 Vrms
> 2 Vrms
1.00%
2.00%
0.30%
0.60%
Open offset Go
Table 43. Open offset Go is given below.
Measurement
time mode
SHORT
MED
Test signal voltage
≤ 2 Vrms
> 2 Vrms
50 nS
500 nS
10 nS
100 nS
Short offset Rs
Table 44. Short offset Rs is given below.
Measurement
time mode
SHORT
MED
Test signal voltage
≤ 2 Vrms
> 2 Vrms
25 mΩ
250 mΩ
5 mΩ
50 mΩ
23
Effect of cable length (Short offset)
Table 45. The following value is added to Rs when the cable is extended.
Cable length
1m
0.25 mΩ
2m
0.5 mΩ
4m
1 mΩ
Temperature coefficient Kt
Table 46. Temperature coefficient Kt is given below.
Temperature [°C]
0 - 18
18 - 28
28 - 55
Kt
4
1
4
Other options
Option 002 (Bias current interface): Adds a digital interface to allow the E4980A LCR
meter to control the Agilent 42841A bias current source.
Option 005 (Entry model): Economy option with less measurement speed.
Same measurement accuracy as the standard model.
Note
Option 007 can be installed only in the E4980A
with option 005.
Option 007 (Standard model): Upgrade to the standard model.
Option 201 (Handler interface): Adds handler interface.
Option 301 (Scanner interface): Adds scanner interface.
24
General specifications
Table 47. Power source
Voltage
Frequency
Power consumption
90 VAC - 264 VAC
47 Hz - 63 Hz
Max. 150 VA
Table 48. Operating environment
0 - 55 °C
15% - 85% RH
Temperature
Humidity
(≤ 40 °C, no condensation)
Altitude
0 m - 2000 m
Table 49. Storage environment
Temperature
Humidity
( ≤ 60 °C, no condensation)
Altitude
–20 - 70 °C
0% - 90% RH
0 m - 4572 m
Outer dimensions: 375 (width) x 105 (height) × 390 (depth) mm (nominal)
367.4
14.4
338.6
14.4
28.0
41.8
E4980A
20 Hz - 2 MHz
Precision LCR Meter
Preset
103.8
Trigger
DC Bias
Display
Format
7
8
9
4
5
6
1
2
3
0
.
DC
Source
USB
UNKNOWN
Discharge test device before connecting
42V Peak Max Output
CAT I
Meas
Setup
DC
Source
55.0
DC
Bias
L CUR
H CUR
H POT
L POT
DC Source
(Option 001)
Return
10VDC Max
Save/
Recall
Recall B
System
Local/
Lock
27.3
Recall A
22
27
55.2
22
40.1
22
Figure 2. Dimensions (front view, with handle and bumper, in millimeters, nominal)
319.1
32.0
20 Hz - 2 MHz
Precision LCR Meter
7
8
9
4
5
6
1
2
3
0
.
DC
Bias
DC
Source
DC Bias
Display
Format
UNKNOWN
Discharge test device before connecting
42V Peak Max Output
CAT I
Meas
Setup
DC
Source
L CUR
Return
USB
H CUR
H POT
L POT
DC Source
(Option 001)
10VDC Max
Recall A
Recall B
Save/
Recall
System
18.0
88.3
21.8
E4980A
Preset
Trigger
Local/
Lock
55.2
27
22
22
22
30.3
Figure 3. Dimensions (front view, without handle and bumper, in millimeters, nominal)
25
367.4
332.2
17.6
17.6
34.7
25.7
23.9
28.0
23.2
26.6
41.6
118.1
Serial Label
E4980A
LAN
101.6
GPIB
Trigger
Option 710: No Interface
Option 710: No Interface
49.3
25.5
55.0
Fuse
T3A , 250V
37
115V
-230V
50/60Hz
150VA MAX
72.3
72.3
31.1
0.4
Option 002: DC Current Control Interface
Option 301: Scanner Interface
36.2
Option 201: Handler Interface
36.2
36.2
72.3
20.9
17.1
113.9
72.3
72.3
Figure 4. Dimensions (rear view, with handle and bumper, in millimeters, nominal)
317.8
41.6
27.5
21.3
23.2
22.2
23.7
19.6
110.9
Serial Label
E4980A
LAN
Trigger
36.5
Fuse
T3A , 250V
37
115V
-230V
50/60Hz
150VA MAX
Option 710: No Interface
Option 710: No Interface
72.3
106.7
72.3
24.0
0.4
Option 002: DC Current Control Interface
Option 301: Scanner Interface
Option 201: Handler Interface
Figure 5. Dimensions (front view, without handle and bumper, in millimeters, nominal)
26
12.7
84.4
GPIB
388.7
55.0
101.6
103.8
66.6
141.4
Figure 6. Dimensions (side view, with handle and bumper, in millimeters, nominal)
374.0
347.9
10.5
45.7
21.9
84.4
88.3
21.9
15.7
19.7
50.9
Figure 7. Dimensions (side view, without handle and bumper, in millimeters, nominal)
Weight: 5.3 kg (nominal)
Display: LCD, 320 × 240 (pixels), RGB color
Note
Effective pixels are more than 99.99%. There
may be 0.01% (approx. 7 pixels) or smaller
missing pixels or constantly lit pixels, but this
is not a malfunction.
The following items can be displayed:
• measurement value
• measurement conditions
• limit value and judgment result of comparator
• list sweep table
• self-test message
27
Description
Supplemental Information
EMC
European Council Directive 89/336/EEC, 92/31/EEC, 93/68/EEC
IEC 61326-1:1997 +A1:1998 +A2:2000
EN 61326-1:1997 +A1:1998 +A2:2001
CISPR 11:1997 +A1:1999 +A2:2002
EN 55011:1998 +A1:1999 +A2:2002 Group 1, Class A
IEC 61000-4-2:1995 +A1:1998 +A2:2001
EN 61000-4-2:1995 +A1:1998 +A2:2001 4 kV CD/8 kV AD
IEC 61000-4-3:1995 +A1:1998 +A2:2001
EN 61000-4-3:1996 +A1:1998 +A2:2001 3 V/m, 80-1000 MHz, 80% AM
IEC 61000-4-4:1995 +A1:2001 +A2:2001
EN 61000-4-4:1995 +A1:2001 +A2:2001 1 kV power /0.5 kV Signal
IEC 61000-4-5:1995 +A1:2001
EN 61000-4-5:1995 +A1:2001 0.5 kV Normal/1 kV Common
IEC 61000-4-6:1996 +A1:2001
EN 61000-4-6:1996 +A1:2001 3 V, 0.15-80 MHz, 80% AM
IEC 61000-4-11:1994 +A1:2001
EN 61000-4-11:1994 +A1:2001 100% 1 cycle
ICES/NMB-001
This ISM device complies with Canadian ICES-001:1998.
Cet appareil ISM est conforme a la norme NMB-001 du Canada.
AS/NZS 2064.1 Group 1, Class A
Safety
European Council Directive 73/23/EEC, 93/68/EEC
IEC 61010-1:2001/EN 61010-1:2001
Measurement Category I, Pollution Degree 2, Indoor Use
IEC60825-1:1994 Class 1 LED
CAN/CSA C22.2 61010-1-04
Measurement Category I, Pollution Degree 2, Indoor Use
Environment
This product complies with the WEEE Directive (2002/96/EC)
marking requirements. The affixed label indicates that you must
not discard this electrical/electronic product in domestic house
hold waste.
Product Category: With reference to the equipment types in the
WEEE Directive Annex I, this product is classed as a “Monitoring
and Control instrumentation” product.
28
Supplemental
Information
Settling time
Table 50. Test frequency setting time
Test frequency setting time
5 ms
12 ms
22 ms
42 ms
Test frequency (Fm)
Fm ≥ 1 kHz
1 kHz > Fm ≥ 250 Hz
250 Hz > Fm ≥ 60 Hz
60 Hz > Fm
Table 51. Test signal voltage setting time
Test signal voltage setting time
11 ms
18 ms
26 ms
48 ms
Test frequency (Fm)
Fm ≥ 1 kHz
1 kHz > Fm ≥ 250 Hz
250 Hz > Fm ≥ 60 Hz
60 Hz > Fm
Switching of the impedance range is as follows:
≤ 5 ms/ range switching
Measurement circuit protection
The maximum discharge withstand voltage, where the internal circuit remains protected
if a charged capacitor is connected to the UNKNOWN terminal, is given below.
Note
Table 52. Maximum discharge withstand voltage
Maximum discharge withstand voltage
Range of capacitance value C of DUT
1000 V
C < 2 µF
√ 2/C V
2 µF ≤ C
1200
1000
Voltage [V]
Discharge capacitors before connecting them
to the UNKNOWN terminal or a test fixture to
avoid damages to the instrument.
800
600
400
200
0
1.E–15
1.E–13
1.E–11
1.E–09
1.E–07
1.E–05
1.E–03
Capacitance [F]
Figure 8. Maximum discharge withstand voltage
29
Measurement time
Definition
This is the time between the trigger and the end of measurement (EOM) output on the
handler interface.
Conditions
Table 53 shows the measurement time when the following conditions are satisfied:
•
•
•
•
•
•
•
•
Normal impedance measurement other than Ls-Rdc, Lp-Rdc, Vdc-Idc
Impedance range mode: hold range mode
DC bias voltage level monitor: OFF
DC bias current level monitor: OFF
Trigger delay: 0 s
Step delay: 0 s
Calibration data: OFF
Display mode: blank
Table 53. Measurement time [ms](DC bias:OFF)
Measurement
time mode
1
2
3
LONG
MED
SHORT
20 Hz
480
380
330
100 Hz
300
180
100
1 kHz
240
110
20
Test frequency
10 kHz
100 kHz
230
220
92
89
7.7
5.7
1 MHz
220
88
5.6
2 MHz
220
88
5.6
10
Measurement time [sec]
1
1. LONG
2. MED
3. SHORT
0.1
0.01
0.001
20
100
1k
10k
Test frequency [Hz]
Figure 9. Measurement time (DC bias: OFF)
30
100k
1M 2M
Table 54. Measurement time when option 005 is installed [ms]
(DC bias: OFF)
Measurement
time mode
1
2
3
20 Hz
1190
1150
1040
LONG
MED
SHORT
100 Hz
650
380
240
Test frequency
1 kHz
10 kHz
590
580
200
180
37
25
100 kHz
570
180
23
1 MHz
570
180
23
2 MHz
570
180
23
10
Measurement time [sec]
1
1. LONG
2. MED
3. SHORT
0.1
0.01
0.001
20
100
1k
10k
100k
1M 2M
Test frequency [Hz]
Figure 10. Measurement time (DC bias: OFF, Option 005)
When DC bias is ON, the following time is added:
Table 55. Additional time when DC bias is ON [ms]
Test frequency
20 Hz
100 Hz
30
30
1 kHz
10
10 kHz
13
100 kHz
2
1 MHz
0.5
2 MHz
0.5
When the number of averaging increases, the measurement time is given as
Equation 17.
MeasTime
Ave
AveTime
MeasTime + (Ave – 1) × AveTime
Measurement time calculated based on Table 53 and Table 54
Number of averaging
Refer to Table 56
Table 56. Additional time per averaging [ms]
Measurement
time mode
SHORT
MED
LONG
20 Hz
51
110
210
100 Hz
11
81
210
1 kHz
2.4
88
220
Test frequency
10 kHz
100 kHz
2.3
2.3
87
85
220
220
1 MHz
2.2
84
210
2 MHz
2.2
84
210
31
Table 57. Measurement time when Vdc-Idc is selected [ms]
Measurement time mode
SHORT
MED
LONG
20 Hz
210
210
410
100 Hz
46
170
410
Test frequency
1 kHz
10 kHz
14
14
170
170
410
410
100 kHz
14
170
410
1 MHz
14
170
410
2 MHz
14
170
410
Add the same measurement time per 1 additional average
Additional Measurement time when the Vdc and Idc monitor function is ON.
Add SHORT mode of Table 57. When using only Vdc or Idc, add a half of SHORT mode of
Table 57.
Table 58. Measurement time when Ls-Rdc or Lp-Rdc is selected [ms]
Measurement time mode
SHORT
MED
LONG
20 Hz
910
1100
1400
100 Hz
230
450
820
Test frequency
1 kHz
10 kHz
43
24
300
280
700
670
100 kHz
22
270
660
1 MHz
22
270
650
2 MHz
22
270
650
Add the three times of measurement time per 1 additional average number
Display time
Except for the case of the DISPLAY BLANK page, the time required to update the display
on each page (display time) is as follows. When a screen is changed, drawing time and
switching time are added. The measurement display is updated about every 100 ms.
Table 59. Display time
32
Item
When Vdc, Idc
monitor is OFF
When Vdc, Idc
monitor is ON
MEAS DISPLAY page drawing time
10 ms
13 ms
MEAS DISPLAY page (large) drawing time
10 ms
13 ms
BIN No. DISPLAY page drawing time
10 ms
13 ms
BIN COUNT DISPLAY page drawing time
10 ms
13 ms
LIST SWEEP DISPLAY page drawing time
40 ms
—
Measurement display switching time
35 ms
—
Measurement data transfer time
This table shows the measurement data transfer time under the following conditions.
The measurement data transfer time varies depending on measurement conditions and
computers.
Table 60. Measurement transfer time under the following conditions:
Host computer:
DELL OPTIPLEX GX260 Pentium 4 2.6 GHz
Display:
ON
Impedance range mode:
AUTO (The overload has not been generated.)
OPEN/SHORT/LOAD compensation:
OFF
Test signal voltage monitor:
OFF
Table 61. Measurement data transfer time [ms]
using :FETC? command
(one point measurement)
Comparator
Comparator
ON
OFF
Data
transfer
format
Interface
using data buffer memory
(list sweep measurement)
10
51
128
201
points
points points points
GPIB
ASCII
ASCII Long
Binary
2
2
2
2
2
2
4
5
4
13
15
10
28
34
21
43
53
32
USB
ASCII
ASCII Long
Binary
2
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ASCII
ASCII Long
Binary
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DC bias test signal current (1.5 V/2.0 V): Output current: Max. 20 mA
Option 001 (Power and DC Bias enhance):
DC bias voltage: DC bias voltage applied to DUT is given as:
Equation 18.
Vdut = Vb – 100 × Ib
Vdut [V] DC bias voltage
Vb [V]
DC bias setting voltage
Ib [A]
DC bias current
DC bias current: DC bias current applied to DUT is given as:
Equation 19.
Idut [A]
Vb [V]
Rdc [Ω]
Idut = Vb/(100 + Rdc)
DC bias current
DC bias setting current
DUT’s DC resistance
33
Maximum DC bias current
Table 62. Maximum DC bias current when the normal measurement
can be performed.
Bias current isolation
Impedance
range [Ω]
0.1
1
10
100
300
1k
3k
10 k
30 k
100 k
ON
Auto range
mode: 100 mA
Hold range mode:
its values for
the range.
Test signal voltage ≤ 2 Vrms
20 mA
20 mA
20 mA
20 mA
2 mA
2 mA
200 µA
200 µA
20 µA
20 µA
OFF
Test signal voltage > 2 Vrms
100 mA
100 mA
100 mA
100 mA
100 mA
20 mA
20 mA
2 mA
2 mA
200 µA
When DC bias is applied to DUT
When DC bias is applied to the DUT, add the following value to the absolute accuracy Ab.
Table 63. Only when Fm < 10 kHz and |Vdc| > 5 V
SHORT
MED, LONG
0.05% × (100 mV/Vs) × (1 + √(100/Fm))
Fm [Hz]
Vs [V]
0.01% × (100 mV/Vs) × (1 + √(100/Fm))
Test frequency
Test signal voltage
Relative measurement accuracy with bias current isolation
When DC bias Isolation is set to ON, add the following value to the open offset Yo.
Equation 20.
Zm [Ω]
Fm [Hz]
Vs [V]
Yo_DCI1,2 [S]
Idc [A]
Yo_DCI1 × (1 + 1/(Vs)) × (1 + √(500/Fm)) + Yo_DCI2
Impedance of DUT
Test frequency
Test signal voltage
Calculate this by using Table 61 and 62
DC bias isolation current
Table 64. Yo_DCI1 value
DC bias current range
20 µA
200 µA
2 mA
20 mA
100 mA
Measurement time mode
SHORT
0S
0.25 nS
2.5 nS
25 nS
250 nS
MED, LONG
0S
0.05 nS
0.5 nS
5 nS
50 nS
Table 65. Yo_DCI2 value
DC bias
current range
20 µA
200 µA
2 mA
20 mA
100 mA
34
≤ 100 Ω
0S
0S
0S
0S
0S
Measurement time mode
300 Ω, 1 k Ω
3 k Ω, 10 k Ω
0S
0S
0S
0S
0S
0S
0S
30 nS
300 nS
300 nS
30 k Ω, 100 k Ω
0S
0S
3 nS
30 nS
300 nS
DC bias settling time
When DC bias is set to ON, add the following value to the settling time:
Table 66. DC bias settling time
Bias
Settling time
1
Standard
Capacitance of DUT × 100 × loge (2/1.8 m) + 3 m
2
Option 001
Capacitance of DUT × 100 × loge (40/1.8 m) + 3 m
100 sec
Settling time
10 sec
1 sec
100 msec
10 msec
2.
1.
1 µF
10 µF
100 µF
1 mF
10 mF
100 mF
DUT capacitance
Figure 11. DC bias settling time
35
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Revised: July 2, 2009
Product specifications and descriptions
in this document subject to change
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© Agilent Technologies, Inc. 2009
Printed in USA, July 31, 2009
5989-4435EN