40LOG (f2/f1
鍙冩暩(sh霉)璩囨枡
鍨嬭櫉锛� AD8202WYRMZ-RL
寤犲晢锛� Analog Devices Inc
鏂囦欢闋佹暩(sh霉)锛� 8/20闋�
鏂囦欢澶�?銆�?/td> 0K
鎻忚堪锛� IC AMP DIFF 50KHZ 8MSOP
鐢�(ch菐n)鍝佸煿瑷�(x霉n)妯″锛� Current Sense Amplifiers
妯�(bi膩o)婧�(zh菙n)鍖呰锛� 3,000
鏀惧ぇ鍣ㄩ鍨嬶細 宸垎
闆昏矾鏁�(sh霉)锛� 1
杞�(zhu菐n)鎻涢€熺巼锛� 0.28 V/µs
澧炵泭甯跺绌嶏細 50kHz
闆绘祦 - 杓稿叆鍋忓锛� 40nA
闆诲 - 杓稿叆鍋忕Щ锛� 2000µV
闆绘祦 - 闆绘簮锛� 250µA
闆诲 - 闆绘簮锛屽柈璺�/闆欒矾(±)锛� 3.5 V ~ 12 V
宸ヤ綔婧害锛� -40°C ~ 125°C
瀹夎椤炲瀷锛� 琛ㄩ潰璨艰
灏佽/澶栨锛� 8-TSSOP锛�8-MSOP锛�0.118"锛�3.00mm 瀵級
渚涙噳(y墨ng)鍟嗚ō(sh猫)鍌欏皝瑁濓細 8-MSOP
鍖呰锛� 甯跺嵎 (TR)
AD8202
Data Sheet
Rev. H | Page 16 of 20
40LOG (f2/f1)
f1
ATTENUATION
f2
f22/f1
FREQUENCY
A 1-POLE FILTER, CORNER f1, AND
A 2-POLE FILTER, CORNER f2, HAVE
THE SAME ATTENUATION 鈥�40LOG (f2/f1)
AT FREQUENCY f22/f1
20dB/DECADE
40dB/DECADE
04981-021
Figure 48. Comparative Responses of 1-Pole and 2-Pole Low-Pass Filters
HIGH LINE CURRENT SENSING WITH LPF AND
GAIN ADJUSTMENT
Figure 49 is another refinement of Figure 2, including gain
adjustment and low-pass filtering.
GND
NC
鈥揑N
+IN
A1
+VS
A2
OUT
AD8202
5V
INDUCTIVE
LOAD
POWER
DEVICE
4-TERM
SHUNT
CLAMP
DIODE
BATTERY
14V
NC = NO CONNECT
COMMON
04981-022
C
OUT
4V/AMP
5% CALIBRATION RANGE
fC(Hz) = 0.796Hz/C(F)
(0.22
F FOR f
C = 3.6Hz)
VOS/IB
NULL
191k
20k
Figure 49. High Line Current Sensor Interface;
Gain = 脳40, Single-Pole, Low-Pass Filter
A power device that is either on or off controls the current in
the load. The average current is proportional to the duty cycle
of the input pulse and is sensed by a small value resistor. The
average differential voltage across the shunt is typically 100 mV,
although its peak value is higher by an amount that depends
on the inductance of the load and the control frequency. The
common-mode voltage, conversely, extends from roughly 1 V
above ground for the on condition to about 1.5 V above the
battery voltage in the off condition. The conduction of the
clamping diode regulates the common-mode potential applied
to the device. For example, a battery spike of 20 V can result
in an applied common-mode potential of 21.5 V to the input
of the devices.
To produce a full-scale output of 4 V, a gain 脳40 is used,
adjustable by 卤5% to absorb the tolerance in the shunt.
Sufficient headroom allows 10% overrange (to 4.4 V). The
roughly triangular voltage across the sense resistor is averaged
by a 1-pole low-pass filter, set with a corner frequency of 3.6 Hz,
providing about 30 dB of attenuation at 100 Hz. A higher rate of
attenuation can be obtained using a 2-pole filter with fC = 20 Hz,
as shown in Figure 50. Although this circuit uses two separate
capacitors, the total capacitance is less than half that needed for
the 1-pole filter.
GND
NC
鈥揑N
+IN
A1
+VS
A2
OUT
AD8202
5V
INDUCTIVE
LOAD
POWER
DEVICE
4-TERM
SHUNT
CLAMP
DIODE
BATTERY
14V
NC = NO CONNECT
COMMON
04981-023
fC(Hz) = 1/C(F)
(0.05
F FOR f
C = 20Hz)
C
OUTPUT
127k
C
432k
50k
Figure 50. 2-Pole Low-Pass Filter
DRIVING CHARGE REDISTRIBUTION ADCS
When driving CMOS ADCs, such as those embedded in
popular microcontrollers, the charge injection (Q) can cause
a significant deflection in the output voltage of the AD8202.
Though generally of short duration, this deflection can persist
until after the sample period of the ADC expires due to the
relatively high open-loop output impedance (typically 21 k)
of the AD8202. Including an R-C network in the output can
significantly reduce the effect. The capacitor helps to absorb the
transient charge, effectively lowering the high frequency output
impedance of the AD8202. For these applications, the output
signal should be taken from the midpoint of the RLAG CLAG
combination, as shown in Figure 51.
Because the perturbations from the analog-to-digital converter
are small, the output impedance of the AD8202 appears to be low.
The transient response, therefore, has a time constant governed
by the product of the two LAG components, CLAG 脳 RLAG. For the
values shown in Figure 51, this time constant is programmed at
approximately 10 s. Therefore, if samples are taken at several
tenths of microseconds or more, there is negligible charge
stack-up.
+IN
鈥揑N
10k
10k
AD8202
5V
R
LAG
1k
C
LAG
0.01
F
MICROPROCESSOR
A/D
A2
2
4
6
5
04981-024
Figure 51. Recommended Circuit for Driving CMOS A/D
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AD8202WYRZ 鍔熻兘鎻忚堪:IC AMP DIFF 50KHZ 8SOIC RoHS:鏄� 椤炲垾:闆嗘垚闆昏矾 (IC) >> Linear - Amplifiers - Instrumentation 绯诲垪:- 妯�(bi膩o)婧�(zh菙n)鍖呰:1 绯诲垪:- 鏀惧ぇ鍣ㄩ鍨�:閫氱敤 闆昏矾鏁�(sh霉):4 杓稿嚭椤炲瀷:婊挎摵骞� 杞�(zhu菐n)鎻涢€熺巼:0.028 V/µs 澧炵泭甯跺绌�:105kHz -3db甯跺:- 闆绘祦 - 杓稿叆鍋忓:3nA 闆诲 - 杓稿叆鍋忕Щ:100µV 闆绘祦 - 闆绘簮:3.3µA 闆绘祦 - 杓稿嚭 / 閫氶亾:12mA 闆诲 - 闆绘簮锛屽柈璺�/闆欒矾(±):2.7 V ~ 12 V锛�±1.35 V ~ 6 V 宸ヤ綔婧害:-40°C ~ 85°C 瀹夎椤炲瀷:琛ㄩ潰璨艰 灏佽/澶栨:14-TSSOP锛�0.173"锛�4.40mm 瀵級 渚涙噳(y墨ng)鍟嗚ō(sh猫)鍌欏皝瑁�:14-TSSOP 鍖呰:鍓垏甯� (CT) 鍏跺畠鍚嶇ū:OP481GRUZ-REELCT
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AD8202YCSURF 鍒堕€犲晢:AD 鍒堕€犲晢鍏ㄧū:Analog Devices 鍔熻兘鎻忚堪:High Common-Mode Voltage, Single-Supply Difference Amplifier
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