Datasheet AD210 (Analog Devices) - 6
| Fabricante | Analog Devices |
| Descripción | Precision, Wide Bandwidth 3-Port Isolation Amplifier |
| Páginas / Página | 9 / 6 — AD210. Phase Shift:. +0.04. +0.03. +0.02. +0.01. –20. G = 1. ERROR – mV. … |
| Revisión | A |
| Formato / tamaño de archivo | PDF / 340 Kb |
| Idioma del documento | Inglés |
AD210. Phase Shift:. +0.04. +0.03. +0.02. +0.01. –20. G = 1. ERROR – mV. ERROR – % –0.01. –40. G = 100. –0.02. –60. –0.03. –80. GAIN – dB. –0.04
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AD210 Phase Shift:
Figure 10 illustrates the AD210’s low phase shift
+0.04 +8
and gain versus frequency. The AD210’s phase shift and wide
+0.03 +6
bandwidth performance make it well suited for applications like power monitors and controls systems.
+0.02 +4 60 0 +0.01 +2 –20 0 0 40
φ
G = 1 ERROR – mV ERROR – % –0.01 –2 20 –40
φ
G = 100 –0.02 –4 0 –60 –0.03 –6 –20 –80 GAIN – dB –0.04 –8 –10 –8 –6 –4 –2 0 +2 +4 +6 +8 +10 –40 –100 PHASE SHIFT – Degrees OUTPUT VOLTAGE SWING – Volts
Figure 12. Gain Nonlinearity Error vs. Output
–60 –120 100 0.01 –80 –140 10 100 1k 10k 100k 90 0.009 FREQUENCY – Hz 80 0.008
Figure 10. Phase Shift and Gain vs. Frequency
70 0.007 Input Noise vs. Frequency:
Voltage noise referred to the input
60 0.006
is dependent on gain and signal bandwidth. Figure 11 illustrates the typical input noise in nV/√Hz of the AD210 for a frequency
50 0.005
range from 10 to 10 kHz.
40 0.004 60 30 0.003 ERROR – % of Signal Swing 20 0.002 ERROR – ppm of Signal Swing 50 10 0.001 0 0.000 40 0 2 4 6 8 10 12 14 16 18 20
√
Hz TOTAL SIGNAL SWING – Volts 30
Figure 13. Gain Nonlinearity vs. Output Swing
Gain vs. Temperature:
Figure 14 illustrates the AD210’s
NOISE – nV/ 20
gain vs. temperature performance. The gain versus temperature performance illustrated is for an AD210 configured as a unity
10
gain amplifier.
400 0 10 100 1k 10k 200 FREQUENCY – Hz G = 1 0
Figure 11. Input Noise vs. Frequency
–200 Gain Nonlinearity vs. Output:
Gain nonlinearity is defined as the
–400
deviation of the output voltage from the best straight line, and is specified as % peak-to-peak of output span. The AD210B provides
–600
guaranteed maximum nonlinearity of ± 0.012% with an output span of
–800
±10 V. The AD210’s nonlinearity performance is shown in Figure 12.
–1000 Gain Nonlinearity vs. Output Swing:
The gain nonlinearity
GAIN ERROR – ppm of Span –1200
of the AD210 varies as a function of total signal swing. When the output swing is less than 20 volts, the gain nonlinearity as a
–1400
fraction of signal swing improves. The shape of the nonlinearity
–1600
remains constant. Figure 13 shows the gain nonlinearity of the
–25 0 +25 +50 +70 +85
AD210 as a function of total signal swing.
TEMPERATURE –
°
C
Figure 14. Gain vs. Temperature REV. A –5–
Figure 10 illustrates the AD210’s low phase shift
+0.04 +8
and gain versus frequency. The AD210’s phase shift and wide
+0.03 +6
bandwidth performance make it well suited for applications like power monitors and controls systems.
+0.02 +4 60 0 +0.01 +2 –20 0 0 40
φ
G = 1 ERROR – mV ERROR – % –0.01 –2 20 –40
φ
G = 100 –0.02 –4 0 –60 –0.03 –6 –20 –80 GAIN – dB –0.04 –8 –10 –8 –6 –4 –2 0 +2 +4 +6 +8 +10 –40 –100 PHASE SHIFT – Degrees OUTPUT VOLTAGE SWING – Volts
Figure 12. Gain Nonlinearity Error vs. Output
–60 –120 100 0.01 –80 –140 10 100 1k 10k 100k 90 0.009 FREQUENCY – Hz 80 0.008
Figure 10. Phase Shift and Gain vs. Frequency
70 0.007 Input Noise vs. Frequency:
Voltage noise referred to the input
60 0.006
is dependent on gain and signal bandwidth. Figure 11 illustrates the typical input noise in nV/√Hz of the AD210 for a frequency
50 0.005
range from 10 to 10 kHz.
40 0.004 60 30 0.003 ERROR – % of Signal Swing 20 0.002 ERROR – ppm of Signal Swing 50 10 0.001 0 0.000 40 0 2 4 6 8 10 12 14 16 18 20
√
Hz TOTAL SIGNAL SWING – Volts 30
Figure 13. Gain Nonlinearity vs. Output Swing
Gain vs. Temperature:
Figure 14 illustrates the AD210’s
NOISE – nV/ 20
gain vs. temperature performance. The gain versus temperature performance illustrated is for an AD210 configured as a unity
10
gain amplifier.
400 0 10 100 1k 10k 200 FREQUENCY – Hz G = 1 0
Figure 11. Input Noise vs. Frequency
–200 Gain Nonlinearity vs. Output:
Gain nonlinearity is defined as the
–400
deviation of the output voltage from the best straight line, and is specified as % peak-to-peak of output span. The AD210B provides
–600
guaranteed maximum nonlinearity of ± 0.012% with an output span of
–800
±10 V. The AD210’s nonlinearity performance is shown in Figure 12.
–1000 Gain Nonlinearity vs. Output Swing:
The gain nonlinearity
GAIN ERROR – ppm of Span –1200
of the AD210 varies as a function of total signal swing. When the output swing is less than 20 volts, the gain nonlinearity as a
–1400
fraction of signal swing improves. The shape of the nonlinearity
–1600
remains constant. Figure 13 shows the gain nonlinearity of the
–25 0 +25 +50 +70 +85
AD210 as a function of total signal swing.
TEMPERATURE –
°
C
Figure 14. Gain vs. Temperature REV. A –5–