LF198JAN_13 [TI]
LF198JAN Monolithic Sample-and-Hold Circuits;
| 型号: | LF198JAN_13 |
| 厂家: | 
TEXAS INSTRUMENTS |
| 描述: | LF198JAN Monolithic Sample-and-Hold Circuits |
| 文件: | 总19页 (文件大小:966K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
LF198JAN
LF198JAN Monolithic Sample-and-Hold Circuits
Literature Number: SNOSAJ2
February 2005
LF198JAN
Monolithic Sample-and-Hold Circuits
General Description
Features
n Operates from 5V to 18V supplies
n Less than 10 µs acquisition time
n TTL, PMOS, CMOS compatible logic input
n 0.5 mV typical hold step at Ch = 0.01 µF
n Low input offset
The LF198 is a monolithic sample-and-hold circuit which
utilizes BI-FET technology to obtain ultra-high dc accuracy
with fast acquisition of signal and low droop rate. Operating
as a unity gain follower, dc gain accuracy is 0.002% typical
and acquisition time is as low as 6 µs to 0.01%. A bipolar
input stage is used to achieve low offset voltage and wide
bandwidth. Input offset adjust is accomplished with a single
pin, and does not degrade input offset drift. The wide band-
width allows the LF198 to be included inside the feedback
loop of 1 MHz op amps without having stability problems.
Input impedance of 1010Ω allows high source impedances to
be used without degrading accuracy.
n 0.002% gain accuracy
n Low output noise in hold mode
n Input characteristics do not change during hold mode
n High supply rejection ratio in sample or hold
n Wide bandwidth
n Space Qualified
P-channel junction FET’s are combined with bipolar devices
in the output amplifier to give droop rates as low as 5 mV/min
with a 1 µF hold capacitor. The JFET’s have much lower
noise than MOS devices used in previous designs and do
not exhibit high temperature instabilities. The overall design
guarantees no feed-through from input to output in the hold
mode, even for input signals equal to the supply voltages.
Logic inputs on the LF198 are fully differential with low input
current, allowing direct connection to TTL, PMOS, and
CMOS. Differential threshold is 1.4V. The LF198 will operate
from 5V to 18V supplies.
Ordering Information
NSC Part Number
JAN Part Number
JM38510/12501BGA
JM38510/12501SGA
NSC Package Number
Package Description
8LD Metal Can
JL198BGA
H08C
H08C
JL198SGA
8LD Metal Can
Connection Diagrams
Metal Can Package
20128114
See NS Package Number H08C
© 2005 National Semiconductor Corporation
DS201281
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Typical Connection and Performance Curve
Acquisition Time
20128132
20128116
Functional Diagram
20128101
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2
Absolute Maximum Ratings (Note 1)
Supply Voltage
18V
500 mW
Power Dissipation (Package Limitation) (Note 2)
Operating Ambient Temperature Range
Storage Temperature Range
−55˚C ≤TA ≤ +125˚C
−65˚C to +150˚C
+150˚C
Maximum Junction Temperature (TJmax
Input Voltage
)
Equal to Supply Voltage
+7V, −30V
Logic To Logic Reference Differential Voltage (Note 3)
Output Short Circuit Duration
Hold Capacitor Short Circuit Duration
Lead Temperature (Soldering, 10 sec.)
Thermal Resistance
Indefinite
10 sec
300˚C
θJA
@
Metal Can (Still Air 0.5W)
160˚C/W
84˚C/W
@
Metal Can (500 LF/Min Air Flow 0.5W)
θJC
Metal Can
48˚C/W
500V
ESD Tolerance (Note 7)
Quality Conformance Inspection
Mil-Std-883, Method 5005 — Group A
Subgroup
Description
Temperature (˚C)
+25˚C
1
2
Static tests at
Static tests at
+125˚C
−55˚C
3
Static tests at
4
Dynamic tests at
Dynamic tests at
Dynamic tests at
Functional tests at
Functional tests at
Functional tests at
Switching tests at
Switching tests at
Switching tests at
+25˚C
5
+125˚C
−55˚C
6
7
+25˚C
8A
8B
9
+125˚C
−55˚C
+25˚C
10
11
+125˚C
−55˚C
3
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Electrical Characteristics
DC Parameters
Symbol
Parameter
Sub-
groups
1
Conditions
Notes
Min Max
Unit
VIO
IIB
ZI
Input Offset Voltage
-3.0
-5.0
-3.0
-5.0
-3.0
-5.0
-3.0
-5.0
-3.0
-5.0
-1.0
-25
-1.0
-25
-1
3.0
5.0
3.0
5.0
3.0
5.0
3.0
5.0
3.0
5.0
25
mV
mV
mV
mV
mV
mV
mV
mV
mV
mV
nA
+VCC = 3.5V, -VCC = -26.5V,
VCM = 11.5V
2, 3
1
+VCC = 26.5V, -VCC = -3.5V,
VCM = -11.5V
2, 3
1
+VCC = 15V, -VCC = -15V,
VCM = 0V
2, 3
1
+VCC = 7V, -VCC = -3V,
VCM = 2V
2, 3
1
+VCC = 3V, -VCC = -7V,
VCM = -2V
2, 3
1
Input Bias Current
+VCC = 3.5V, -VCC = -26.5V,
VCM = 11.5V
75
nA
2, 3
1
25
nA
+VCC = 26.5V, -VCC = -3.5V,VCM
= -11.5V
75
nA
2, 3
1
25
nA
+VCC = 15V, -VCC = -15V,
VCM = 0V
-25
-1
75
nA
2, 3
1
25
nA
+VCC = 7V, -VCC = -3V,
VCM = 2V
-25
-1.0
-25
75
nA
2, 3
1
25
nA
+VCC = 3V, -VCC = -7V,
VCM = -2V
75
nA
2, 3
Input Impedance
+VCC = 3.5V to 26.6V,
-VCC = -26.5V to -3.5V,
VCM = 11.5V to -11.5V
2.0
1.0
GΩ
GΩ
1
2, 3
VIO Adj
VIO Adj
+
-
Input Offset Voltage Adjustment +VCC = 15V, -VCC = -15V,
6.0
mV
mV
dB
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
VCM = 0V
Input Offset Voltage Adjustment +VCC = 15V, -VCC = -15V,
VCM = 0V
-6.0
PSRR+
PSRR-
ICC
Power Supply Rejection Ratio
Power Supply Rejection Ratio
Supply Current
-VCC = -18V,
80
80
+VCC = 18V to 12V
+VCC = 18V,
dB
-VCC = -12V to -18V
1.0
1.0
5.5
6.5
mA
mA
1,2
3
+VCC = 15V, -VCC = -15V,
VCM = 0V
AE
Gain Error
+VCC = 3.5V to 26.5V,
-VCC = -26.5V to -3.5V,
VCM = -11.5V to 11.5V
+VCC = 3V to 7V,
-0.005 0.005
-0.02 0.02
-0.02 0.02
-0.04 0.04
%
%
%
%
1
2, 3
1
-VCC = -7V to -3V,
2, 3
VCM = -2V to 2V
RSC
Series Charge Resistance
+VCC = 15V, -VCC = -15V,
VCM = 0V
75
400
Ω
1, 2, 3
I
I
I
IH (a)
IH (b)
IL (a)
Logical 1 Input Current
Logical 1 Input Current
Logical 0 Input Current
Logical 0 Input Current
Output Short Circuit Current
+VCC = 8.5V, -VCC = -21.5V
+VCC = 8.5V, -VCC = -21.5V
+VCC = 21.5V, -VCC = -8.5V
+VCC = 21.5V, -VCC = -8.5V
+VCC = 15V, -VCC = -15V,
VCM = 0V
0
10
10
µA
µA
µA
µA
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
0
-1.0
-1.0
1.0
1.0
IIL (b)
IOS
+
-25
mA
1, 2, 3
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4
Electrical Characteristics (Continued)
DC Parameters (Continued)
Symbol
Parameter
Sub-
groups
Conditions
Notes
Min Max
Unit
IOS
ICH
ICH
-
Output Short Circuit Current
Hold Capacitor Charge Current
Hold Capacitor Charge Current
Differential Logic Threshold
+VCC = 15V, -VCC = -15V,
VCM = 0V
25
mA
1, 2, 3
+
-
-3.0
-2.0
mA
mA
mA
mA
1
+VCC = 15V, -VCC = -15V,
VCM = 0V
2, 3
1
3.0
+VCC = 15V, -VCC = -15V,
VCM = 0V
2.0
2, 3
V
V
Th(H)
Th(L)
+VCC = 15V, -VCC = -15V,
VCM = 0V
1.0
mA
µA
1, 2, 3
1, 2, 3
Logic = 2.0V, Logic Ref = 2.0V
+VCC = 15V, -VCC = -15V,
VCM = 0V
Differential Logic Threshold
-10
10
Logic = 0.8V, Logic Ref = 2.0V
IHL
IHL
ZO
+
Hold Mode Leakage Current
Hold Mode Leakage Current
Output Impedance
(Note 5) -0.100 0.100
-50 50
(Note 5) -0.100 0.100
nA
nA
nA
nA
1
2
1
2
+VCC = 3.5V, -VCC = -26.5V,
VCM = -11.5V
-
+VCC = 26.5V, -VCC = -3.5V,
VCM = 11.5V
-50
50
+VCC = 15V, -VCC = -15V,
VCM = 0V
2.0
Ω
1, 2, 3
VHS
(HOLD) Step Voltage
(Note 4)
(Note 4)
-2.0
-5.0
-2.0
-5.0
86
2.0
5.0
2.0
5.0
mV
mV
mV
mV
dB
dB
dB
dB
dB
dB
dB
dB
1
2, 3
1
+VCC = 3.5V, -VCC = -26.5V,
VCM = 11.5V
+VCC = 26.5V, -VCC = -3.5V,
VCM = -11.5V
2, 3
1
FRR
Feedthrough Rejection Ratio
+VCC = 15V, -VCC = -15V,
VCM = 0V, VI = 0V to 11.5V
80
2, 3
1
86
+VCC = 15V, -VCC = -15V,
VCM = 0V, VI = 11.5V to 0V
80
2, 3
1
86
+VCC = 15V, -VCC = -15V,
VCM = 0V, VI = 0V to -11.5V
80
2, 3
1
86
+VCC = 15V, -VCC = -15V,
VCM = 0V, VI = -11.5V to 0V
80
2, 3
AC/DC Parameters
Symbol
Parameter
Sub-
groups
Conditions
Notes
Min Max
Unit
Delta VIO
Delta T
TAQ
/
Input Offset Voltage Temp
Sensitivity
-20
20
µV/˚C
8A, 8B
Aquisition Time
+VCC = 15V, -VCC = -15V
+VCC = 15V, -VCC = -15V
+VCC = 15V, -VCC = -15V
+VCC = 15V, -VCC = -15V,
VI = 20Vpp
25
300
1.5
µS
nS
µS
7
7
7
TAP
Aperture Time
TS
Settling Time
FRR AC
Feedthrough Rejection Ratio
86
dB
µS
µS
7
7
7
TRTS
Transient Response (settling
time)
+VCC = 3.5V, -VCC = -26.5V,
VI = 100mV pulse
2.5
2.5
+VCC = 26.5V, -VCC = -3.5V,
VI = 100mV pulse
5
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AC/DC Parameters (Continued)
Symbol
Parameter
Sub-
groups
Conditions
Notes
Min Max
Unit
%
TROS
Transient Response
(overshoot)
+VCC = 3.5V, -VCC = -26.5V,
VI = 100mV pulse
40
40
7
7
+VCC = 26.5V, -VCC = -3.5V,
VI = 100mV pulse
%
enH
enS
Noise
Noise
+VCC = 15V, -VCC = -15V
+VCC = 15V, -VCC = -15V
10
10
mVRMS
mVRMS
7
7
DC Parameters: Drift Values
Delta calculations performed on S-Level devices at group B, subgroup 5 ONLY.
Symbol
VIO
IIB
Parameters
Input Offset Voltage
Input Bias Current
Conditions
Sub-
groups
Notes
Min Max
Unit
mV
nA
+VCC = 15V, -VCC = -15V,
VCM = 0V
-0.5
-2.5
0.5
2.5
1
1
+VCC = 15V, -VCC = -15V,
VCM = 0V
Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed
specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test
conditions
Note 2: The maximum power dissipation must be derated at elevated temperatures and is dictated by T
, θ , and the ambient temperature, T . The maximum
A
JMAX JA
allowable power dissipation at any temperature is P = (T
− T )/θ , or the number given in the Absolute Maximum Ratings, whichever is lower. .
A JA
D
JMAX
Note 3: Although the differential voltage may not exceed the limits given, the common-mode voltage on the logic pins may be equal to the supply voltages without
causing damage to the circuit. For proper logic operation, however, one of the logic pins must always be at least 2V below the positive supply and 3V above the
negative supply.
Note 4: Hold step is sensitive to stray capacitive coupling between input logic signals and the hold capacitor. 1 pF, for instance, will create an additional 0.5 mV step
with a 5V logic swing and a 0.01µF hold capacitor. Magnitude of the hold step is inversely proportional to hold capacitor value.
Note 5: Leakage current is measured at a junction temperature of 25˚C. The effects of junction temperature rise due to power dissipation or elevated ambient can
be calculated by doubling the 25˚C value for each 11˚C increase in chip temperature. Leakage is guaranteed over full input signal range.
Note 6: See Definition of Terms
Note 7: Human body model, 100pF discharged through 1.5KΩ
Typical Performance Characteristics
Aperture Time
Dielectric Absorption
Error in Hold Capacitor
(Note 6)
20128117
20128118
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6
Typical Performance Characteristics (Continued)
Dynamic Sampling Error
(Note 6)
Output Droop Rate
20128119
20128120
Hold Step
“Hold” Settling Time
(Note 6)
(Note 6)
20128121
20128122
Leakage Current into Hold
Capacitor
Phase and Gain (Input to
Output, Small Signal)
20128123
20128124
7
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Typical Performance Characteristics (Continued)
Gain Error
Power Supply Rejection
20128126
20128125
Output Short Circuit Current
Output Noise
20128127
20128128
Note 8: See Definition
Feedthrough Rejection Ratio
(Hold Mode)
Input Bias Current
20128130
20128129
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8
Typical Performance Characteristics (Continued)
Output Transient at Start
of Sample Mode
Hold Step vs Input Voltage
20128131
20128112
Output Transient at Start
of Hold Mode
20128113
Logic Input Configurations
TTL & CMOS
3V ≤ VLOGIC (Hi State) ≤ 7V
20128133
Threshold = 1.4V
20128134
Threshold = 1.4V*Select for 2.8V at pin 8
9
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Logic Input Configurations (Continued)
CMOS
7V ≤ VLOGIC (Hi State) ≤ 15V
20128135
+
Threshold = 0.6 (V ) + 1.4V
20128136
+
Threshold = 0.6 (V ) − 1.4V
Op Amp Drive
20128137
Threshold ≈ +4V
20128138
Threshold = −4V
The hysteresis numbers on the curve are final values, taken
after full relaxation. The hysteresis error can be significantly
reduced if the output of the LF198 is digitized quickly after
the hold mode is initiated. The hysteresis relaxation time
constant in polypropylene, for instance, is 10—50 ms. If
A-to-D conversion can be made within 1 ms, hysteresis error
will be reduced by a factor of ten.
Application Hints
HOLD CAPACITOR
Hold step, acquisition time, and droop rate are the major
trade-offs in the selection of a hold capacitor value. Size and
cost may also become important for larger values. Use of the
curves included with this data sheet should be helpful in
selecting a reasonable value of capacitance. Keep in mind
that for fast repetition rates or tracking fast signals, the
capacitor drive currents may cause a significant temperature
rise in the LF198.
DC AND AC ZEROING
DC zeroing is accomplished by connecting the offset adjust
pin to the wiper of a 1 kΩ potentiometer which has one end
tied to V+ and the other end tied through a resistor to ground.
The resistor should be selected to give ≈0.6 mA through the
1k potentiometer.
A significant source of error in an accurate sample and hold
circuit is dielectric absorption in the hold capacitor. A mylar
cap, for instance, may “sag back” up to 0.2% after a quick
change in voltage. A long sample time is required before the
circuit can be put back into the hold mode with this type of
capacitor. Dielectrics with very low hysteresis are polysty-
rene, polypropylene, and Teflon. Other types such as mica
and polycarbonate are not nearly as good. The advantage of
polypropylene over polystyrene is that it extends the maxi-
mum ambient temperature from 85˚C to 100˚C. Most ce-
AC zeroing (hold step zeroing) can be obtained by adding an
inverter with the adjustment pot tied input to output. A 10 pF
capacitor from the wiper to the hold capacitor will give 4 mV
hold step adjustment with a 0.01 µF hold capacitor and 5V
logic supply. For larger logic swings, a smaller capacitor
<
(
10 pF) may be used.
LOGIC RISE TIME
>
ramic capacitors are unusable with
1% hysteresis. Ce-
For proper operation, logic signals into the LF198 must have
a minimum dV/dt of 1.0 V/µs. Slower signals will cause
excessive hold step. If a R/C network is used in front of the
ramic “NPO” or “COG” capacitors are now available for
125˚C operation and also have low dielectric absorption. For
more exact data, see the curve Dielectric Absorption Error.
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10
A second curve, Hold Settling Time indicates the time re-
quired for the output to settle to 1 mV after the “hold”
command.
Application Hints (Continued)
logic input for signal delay, calculate the slope of the wave-
form at the threshold point to ensure that it is at least
1.0 V/µs.
DIGITAL FEEDTHROUGH
Fast rise time logic signals can cause hold errors by feeding
externally into the analog input at the same time the amplifier
is put into the hold mode. To minimize this problem, board
layout should keep logic lines as far as possible from the
analog input and the Ch pin. Grounded guarding traces may
also be used around the input line, especially if it is driven
from a high impedance source. Reducing high amplitude
logic signals to 2.5V will also help.
SAMPLING DYNAMIC SIGNALS
Sample error to moving input signals probably causes more
confusion among sample-and-hold users than any other pa-
rameter. The primary reason for this is that many users make
the assumption that the sample and hold amplifier is truly
locked on to the input signal while in the sample mode. In
actuality, there are finite phase delays through the circuit
creating an input-output differential for fast moving signals.
In addition, although the output may have settled, the hold
capacitor has an additional lag due to the 300Ω series
resistor on the chip. This means that at the moment the
“hold” command arrives, the hold capacitor voltage may be
somewhat different than the actual analog input. The effect
of these delays is opposite to the effect created by delays in
the logic which switches the circuit from sample to hold. For
example, consider an analog input of 20 Vp-p at 10 kHz.
Maximum dV/dt is 0.6 V/µs. With no analog phase delay and
100 ns logic delay, one could expect up to (0.1 µs) (0.6V/µs)
= 60 mVerror if the “hold” signal arrived near maximum dV/dt
of the input. A positive-going input would give a +60 mV
error. Now assume a 1 MHz (3 dB) bandwidth for the overall
analog loop. This generates a phase delay of 160 ns. If the
hold capacitor sees this exact delay, then error due to analog
delay will be (0.16 µs) (0.6 V/µs) = −96 mV. Total output error
is +60 mV (digital) −96 mV (analog) for a total of −36 mV. To
add to the confusion, analog delay is proportioned to hold
capacitor value while digital delay remains constant. A family
of curves (dynamic sampling error) is included to help esti-
mate errors.
Guarding Technique
20128105
Use 10-pin layout. Guard around Chis tied to output.
A curve labeled Aperture Time has been included for sam-
pling conditions where the input is steady during the sam-
pling period, but may experience a sudden change nearly
coincident with the “hold” command. This curve is based on
a 1 mV error fed into the output.
11
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Typical Applications
Sample and Difference Circuit
X1000 Sample & Hold
(Output Follows Input in Hold Mode)
20128140
V
= V + ∆V (HOLD MODE)
B IN
OUT
20128139
*For lower gains, the LM108 must be frequency compensated
Ramp Generator with Variable Reset Level
Integrator with Programmable Reset Level
20128142
20128143
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12
Typical Applications (Continued)
Output Holds at Average of Sampled Input
Increased Slew Current
20128146
20128147
Reset Stabilized Amplifier (Gain of 1000)
Fast Acquisition, Low Droop Sample & Hold
20128149
20128150
13
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Typical Applications (Continued)
Synchronous Correlator for Recovering
Signals Below Noise Level
2–Channel Switch
20128153
20128152
A
B
Gain
ZIN
1
1010
0.02%
Ω
1
0.2%
47 kΩ
BW
. 1 MHz
. 400 kHz
−90 dB
Crosstalk −90 dB
@
1 kHz
Offset
≤ 6 mV
≤ 75 mV
DC & AC Zeroing
Staircase Generator
20128155
*Select for step height
20128159
→
50k
≅ 1V Step
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14
Typical Applications (Continued)
Differential Hold
Capacitor Hysteresis Compensation
20128156
20128157
**Adjust for amplitude
Hold Settling Time: The time required for the output to
settle within 1 mV of final value after the “hold” logic com-
mand.
Definition of Terms
Hold Step: The voltage step at the output of the sample and
hold when switching from sample mode to hold mode with a
steady (dc) analog input voltage. Logic swing is 5V.
Dynamic Sampling Error: The error introduced into the
held output due to a changing analog input at the time the
hold command is given. Error is expressed in mV with a
given hold capacitor value and input slew rate. Note that this
error term occurs even for long sample times.
Acquisition Time: The time required to acquire a new ana-
log input voltage with an output step of 10V. Note that
acquisition time is not just the time required for the output to
settle, but also includes the time required for all internal
nodes to settle so that the output assumes the proper value
when switched to the hold mode.
Aperture Time: The delay required between “Hold” com-
mand and an input analog transition, so that the transition
does not affect the held output.
Gain Error: The ratio of output voltage swing to input volt-
age swing in the sample mode expressed as a per cent
difference.
15
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Revision History Section
Date
Revision
Section
Originator
Changes
Released
02/25/05
A
New release, Corporate format
L. Lytle
1 MDS converted to corp. datasheet
format. MJLF198–X Rev 2B0 MDS to be
archived.
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16
Physical Dimensions inches (millimeters) unless otherwise noted
Metal Can Package (H)
NS Package Number H08C
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the right at any time without notice to change said circuitry and specifications.
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