LINER LTC1414CGN

LTC1414
14-Bit, 2.2Msps,
Sampling A/D Converter
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DESCRIPTIO
FEATURES
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Sample Rate: 2.2Msps
Outstanding Spectral Purity:
80dB S/(N + D) and 95dB SFDR at 100kHz
78dB S/(N + D) and 84dB SFDR at Nyquist
Ultralow Distortion with Single-Ended or
Differential Inputs
±2.5V Bipolar Input Range Eliminates Level Shifting
and Rail-to-Rail Op Amp Requirements
Easy Hookup for External or Internal Reference
No Pipeline Delay
Power Dissipation: 175mW on ±5V Supplies
28-Pin Narrow SSOP Package
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The LTC1414’s high performance sample-and-hold has a
full-scale input range of ±2.5V. Outstanding AC performance includes 80dB S/(N + D) and 95dB SFDR with a
100kHz input. The performance remains high at the Nyquist
input frequency of 1.1MHz with 78dB S/(N + D) and 84dB
SFDR.
The unique differential input sample-and-hold can acquire
single-ended or differential input signals up to its 40MHz
bandwidth. The 70dB common mode rejection can eliminate ground loops and common mode noise by measuring
signal differentially from the source
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APPLICATIO S
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The LTC ®1414 is a 14-bit, 2.2Msps, sampling A/D converter which draws only 175mW from ±5V supplies. This
high performance ADC includes a high dynamic range
sample-and-hold, a precision reference and requires no
external components.
Telecommunications
Digital Signal Processing
Multiplexed Data Acquisition Systems
High Speed Data Acquisition
Spectrum Analysis
Imaging Systems
The ADC has a microprocessor compatible, 14-bit parallel
output port. There is no pipline delay in the conversion
results.
, LTC and LT are registered trademarks of Linear Technology Corporation.
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TYPICAL APPLICATIO
OPTIONAL 3V
LOGIC SUPPLY
5V
Effective Bits and Signal-to-Noise + Distortion
vs Input Frequency
10µF
AVDD
DVDD
OVDD
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OUTPUT
BUFFERS
14-BIT ADC
S/H
AIN –
•
•
•
D13 (MSB)
D0 (LSB)
4.0625V
COMP
80
12
74
11
68
10
9
8
7
6
5
BUFFER
10µF
86
13
S/(N + D) (dB)
AIN +
EFFECTIVE BITS
LTC1414
14
4
2k
VREF
2.5V
REFERENCE
TIMING AND
LOGIC
1µF
VSS
10µF
AGND
DGND
BUSY
3
CONVST
2
OGND
fSAMPLE = 2.2MHz
1k
10k
100k
1M
INPUT FREQUENCY (Hz)
10M
1414 TA02
1414 TA01
– 5V
1
LTC1414
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ABSOLUTE MAXIMUM RATINGS
PACKAGE/ORDER INFORMATION
AVDD = OVDD = DVDD = VDD (Notes 1, 2)
ORDER PART
NUMBER
TOP VIEW
Supply Voltage (VDD) ................................................. 6V
Negative Supply Voltage (VSS) ................................ – 6V
Total Supply Voltage (VDD to VSS) .......................... 12V
Analog Input Voltage
(Note 3) ......................... (VSS – 0.3V) to (VDD + 0.3V)
Digital Input Voltage (Note 4) ..........(VSS – 0.3V) to 10V
Digital Output Voltage ........ (VSS – 0.3V) to (VDD + 0.3V)
Power Dissipation.............................................. 500mW
Operating Temperature Range ..................... 0°C to 70°C
Storage Temperature Range ................. – 65°C to 150°C
Lead Temperature (Soldering, 10 sec).................. 300°C
AIN+
AIN–
1
28 AVDD
2
27 AGND
VREF
3
26 VSS
REFCOMP
4
25 BUSY
AGND
5
24 CONVST
D13 (MSB)
6
23 DGND
D12
7
22 DVDD
D11
8
21 OVDD
D10
9
20 D0
D9 10
19 D1
D8 11
18 D2
D7 12
17 D3
D6 13
16 D4
OGND 14
15 D5
LTC1414CGN
GN PACKAGE
28-LEAD PLASTIC SSOP
TJMAX = 110°C, θJA = 110°C/ W
Consult factory for Industrial, Military and A grade parts.
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CO VERTER CHARACTERISTICS
PARAMETER
With internal reference (Notes 5, 6)
LTC1414
TYP
MAX
UNITS
●
±0.75
±2.0
LSB
●
±0.75
± 1.75
LSB
±5
±20
±24
LSB
LSB
±60
±25
LSB
LSB
CONDITIONS
MIN
Resolution (No Missing Codes)
Integral Linearity Error
●
(Note 7)
Differential Linearity Error
Offset Error
13
(Note 8)
Bits
●
Full-Scale Error
Internal Reference
External Reference = 2.5V
±10
±5
Full-Scale Tempco
Internal Reference
External Reference = 2.5V
±15
±1
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A ALOG I PUT
(Note 5)
SYMBOL PARAMETER
CONDITIONS
VIN
Analog Input Range
4.75V ≤ VDD ≤ 5.25V, – 5.25V ≤ VSS ≤ – 4.75V
●
IIN
Analog Input Leakage Current
Between Conversions
●
CIN
Analog Input Capacitance
Between Conversions
During Conversions
tACQ
Sample-and-Hold Acquisition Time
tAP
Sample-and-Hold Aperture Delay Time
tjitter
Sample-and-Hold Aperture Delay Time Jitter
CMRR
2
ppm/°C
ppm/°C
Analog Input Common Mode Rejection Ratio
MIN
MAX
±2.5
40
UNITS
V
±1
8
4
●
– 2.5V < (AIN– = AIN+) < 2.5V
TYP
µA
pF
pF
100
ns
–1
ns
3
psRMS
70
dB
LTC1414
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DY A IC ACCURACY
(Note 5)
SYMBOL PARAMETER
CONDITIONS
S/(N + D) Signal-to-Noise Plus Distortion Ratio
100kHz Input Signal
1.1MHz Input Signal
THD
Total Harmonic Distortion
SFDR
IMD
MIN
TYP
MAX
UNITS
80
78
dB
dB
100kHz Input Signal, First 5 Harmonics
1.1MHz Input Signal, First 5 Harmonics
– 95
– 83
dB
dB
Spurious Free Dynamic Range
100kHz Input Signal, First 5 Harmonics
1.1MHz Input Signal, First 5 Harmonics
95
84
dB
dB
Intermodulation Distortion
fIN1 = 29.37kHz, fIN2 = 32.446kHz
Full Power Bandwidth
S/(N + D) ≥ 74dB
Full Linear Bandwidth
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I TER AL REFERE CE CHARACTERISTICS
– 86
dB
40
MHz
3
MHz
(Note 5)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VREF Output Voltage
IOUT = 0
2.480
2.500
2.520
V
VREF Output Tempco
IOUT = 0
±15
ppm/°C
VREF Line Regulation
4.75V ≤ VDD ≤ 5.25V
– 5.25V ≤ VSS ≤ – 4.75V
0.01
0.01
LSB/ V
LSB/ V
VREF Output Resistance
IOUT ≤ 0.1mA
COMP Output Voltage
IOUT = 0
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DIGITAL I PUTS AND OUTPUTS
SYMBOL PARAMETER
2
kΩ
4.06
V
(Note 5)
CONDITIONS
MIN
TYP
MAX
VIH
High Level Input Voltage
VDD = 5.25V
●
VIL
Low Level Input Voltage
VDD = 4.75V
●
0.8
V
IIN
Digital Input Current
VIN = 0V to VDD
●
±10
µA
CIN
Digital Input Capacitance
VOH
High Level Output Voltage
VOL
Low Level Output Voltage
VDD = 4.75V, IO = – 10µA
VDD = 4.75V, IO = – 200µA
●
VDD = 4.75V, IO = 160µA
VDD = 4.75V, IO = 1.6mA
●
2.4
UNITS
V
1.2
pF
4.74
V
V
4.0
0.05
0.10
0.4
V
V
ISOURCE
Output Source Current
VOUT = 0V
– 10
mA
ISINK
Output Sink Current
VOUT = VDD
10
mA
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POWER REQUIRE E TS
(Note 5)
SYMBOL PARAMETER
CONDITIONS
MIN
MAX
UNITS
VDD
Positive Supply Voltage
(Note 9)
4.75
TYP
5.25
V
VSS
Negative Supply Voltage
(Note 9)
– 4.75
– 5.25
V
IDD
Positive Supply Current
CS High
●
12
16
mA
ISS
Negative Supply Current
CS High
●
23
30
mA
PD
Power Dissipation
175
230
mW
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LTC1414
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TI I G CHARACTERISTICS
(Note 5)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
fSAMPLE(MAX)
Maximum Sampling Frequency
●
2.2
tCONV
Conversion Time
●
220
330
400
ns
tACQ
Acquisition Time
●
40
100
ns
tTHROUGHPUT
Throughput Time (Acquisition + Conversion)
t1
CONVST to BUSY Delay
●
370
454
t2
Data Ready Before BUSY↑
t3
Delay Between Conversions
(Note 9)
●
100
ns
t4
CONVST Low Time
(Note 10)
●
40
ns
t5
CONVST High Time
(Note 10)
●
40
ns
t6
Aperture Delay of Sample-and-Hold
CL = 25pF
UNITS
MHz
ns
10
ns
±20
ns
–1
The ● denotes specifications which apply over the full operating
temperature range; all other limits and typicals TA = 25°C.
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: All voltage values are with respect to ground with DGND and
AGND wired together (unless otherwise noted).
Note 3: When these pin voltages are taken below VSS or above VDD, they
will be clamped by internal diodes. This product can handle input currents
greater than 100mA below VSS or above VDD without latchup.
Note 4: When these pin voltages are taken below VSS, they will be clamped
by internal diodes. This product can handle input currents greater than
100mA below VSS without latchup. These pins are not clamped to VDD.
Note 5: VDD = 5V, VSS = – 5V, fSAMPLE = 2.2MHz and tr = tf = 5ns unless
otherwise specified.
ns
Note 6: Linearity, offset and full-scale specifications apply for a singleended AIN+ input with AIN– grounded.
Note 7: Integral nonlinearity is defined as the deviation of a code from a
straight line passing through the actual endpoints of the transfer curve.
The deviation is measured from the center of the quantization band.
Note 8: Bipolar offset is the offset voltage measured from – 0.5LSB
when the output code flickers between 0000 0000 0000 00 and
1111 1111 1111 11.
Note 9: Recommended operating conditions.
Note 10: The falling CONVST edge starts a conversion. If CONVST returns
high at a critical point during the conversion it can create small errors. For
best results ensure that CONVST returns high either within 225ns after the
start of the conversion or after BUSY rises.
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TYPICAL PERFOR A CE CHARACTERISTICS
Signal-to-Noise Ratio vs Input
Frequency
Distortion vs Input Frequency
86
90
0
13
80
80
–10
12
74
11
68
9
8
7
6
5
4
3
fSAMPLE = 2.2MHz
2
1k
10k
100k
1M
INPUT FREQUENCY (Hz)
10M
1414 TA02
4
–20
70
DISTORTION (dB)
10
SIGNAL-TO-NOISE RATIO (dB)
14
S/(N + D) (dB)
EFFECTIVE BITS
S/(N + D) vs Input Frequency
60
50
40
30
–30
–40
–50
–70
20
–80
10
–90
0
10k
100k
1M
INPUT FREQUENCY (Hz)
10M
1414 G02
THD
–60
–100
10k
3rd
2nd
100k
1M
INPUT FREQUENCY (Hz)
10M
1414 G03
LTC1414
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TYPICAL PERFOR A CE CHARACTERISTICS
Spurious-Free Dynamic Range vs
Input Frequency
0
2.0
0
fSAMPLE = 2.2MHz
fIN1 = 80.566kHz
fIN2 = 97.753kHz
–10
–20
–20
–40
–50
–60
–70
1.0
–40
DNL (LSBs)
–30
AMPLITUDE (dB)
SPURIOUS-FREE DYNAMIC RANGE (dB)
Differential Nonlinearity vs
Output Code
Intermodulation Distortion Plot
–60
0
–80
–1.0
–80
–100
–90
–100
10k
–120
100k
1M
INPUT FREQUENCY (Hz)
10M
–2.0
0
200
400
600
800
FREQUENCY (kHz)
0
1000
4096
8192
12288
OUTPUT CODE
16384
1414 G04
1414 G06
1414 F05a
Integral Nonlinearity vs Output
Code
Power Supply Feedthrough vs
Ripple Frequency
2.0
80
0
–1.0
VSS (VRIPPLE = 0.02V)
VDD (VRIPPLE = 0.2V)
OGND (VRIPPLE = 0.5V)
OVDD (VRIPPLE = 0.5V)
–20
COMMON MODE REJECTION (dB)
AMPLITUDE OF POWER SUPPLY
FEEDTHROUGH (dB)
0
1.0
INL (LSBs)
Input Common Mode Rejection vs
Input Frequency
–40
–60
–80
–100
–2.0
0
4096
8192
12288
OUTPUT CODE
16384
70
60
50
40
30
20
10
0
–120
0
2M
4M
6M
8M
RIPPLE FREQUENCY (Hz)
1414 G07
10M
1k
1M
10k
100k
INPUT FREQUENCY (Hz)
1414 G08
10M
LTC1414 • F12
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PIN FUNCTIONS
A IN+ (Pin 1): Positive Analog Input. ±2.5V input range
when AIN– is grounded. ±2.5V differential if AIN– is driven
differentially with AIN+.
AIN– (Pin 2): Negative Analog Input. Can be grounded or
driven differentially with AIN+.
VREF (Pin 3): 2.5V Reference Output.
OGND (Pin 14): Digital Ground for the Output Drivers. Tie
to AGND
D5 to D0 (Pins 15 to 20): Data Outputs.
OVDD (Pin 21): Positive Supply for the Output Drivers. Tie
to Pin 28 when driving 5V logic. For 3V logic, tie to supply
of the logic being driven.
REFCOMP (Pin 4): 4.06V Reference Bypass Pin.
Bypass to AGND with 10µF ceramic or 10µF tantalum in
parallel with 0.1µF ceramic.
DVDD (Pin 22): 5V Positive Supply. Tie to Pin 28.
DGND (Pin 23): Digital Ground. Tie to AGND.
AGND (Pin 5): Analog Ground.
CONVST (Pin 24): Conversion Start Signal. This active low
signal starts a conversion on its falling edge.
D13 to D6 (Pins 6 to 13): Data Outputs.
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LTC1414
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PIN FUNCTIONS
BUSY (Pin 25): The BUSY Output Shows the Converter
Status. It is low when a conversion is in progress.
AGND (Pin 27): Analog Ground.
AVDD (Pin 28): 5V Positive Supply. Bypass to AGND with
10µF ceramic or 10µF tantalum in parallel with 0.1µF
ceramic.
VSS (Pin 26): – 5V Negative Supply. Bypass to AGND with
10µF ceramic or 10µF tantalum in parallel with 0.1µF
ceramic.
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FUNCTIONAL BLOCK DIAGRA
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CSAMPLE
AIN+
AVDD
CSAMPLE
DVDD
AIN–
2k
VREF
VSS
ZEROING SWITCHES
2.5V REF
+
REF AMP
COMP
14-BIT CAPACITIVE DAC
–
REFCOMP
(4.06V)
OVDD
14
SUCCESSIVE APPROXIMATION
REGISTER
AGND
OUTPUT
LATCHES
•
•
•
D13
D0
OGND
INTERNAL
CLOCK
DGND
CONTROL LOGIC
1414 BD
CONVST
BUSY
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TI I G DIAGRA
tCONV
t4
t5
CONVST
t1
t3
BUSY
t2
DATA
6
DATA (N – 1)
DB13 TO DB0
DATA N
DB13 TO DB0
DATA (N + 1)
DB13 TO DB0
1414 TD
LTC1414
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APPLICATIONS INFORMATION
CONVERSION DETAILS
The LTC1414 uses a successive approximation algorithm
and an internal sample-and-hold circuit to convert an
analog signal to a 14-bit parallel output. The ADC is
complete with a precision reference and an internal clock.
The device is easy to interface with microprocessors and
DSPs. (Please refer to the Digital Interface section for the
data format.)
AIN+
AIN–
CSAMPLE+
SAMPLE
CSAMPLE–
SAMPLE
HOLD
HOLD
HOLD
CDAC+
+
CDAC–
VDAC+
Conversion start is controlled by the CONVST input. At the
start of the conversion the successive approximation
register (SAR) is reset. Once a conversion cycle has begun
it cannot be restarted.
COMP
–
VDAC–
14
SAR
OUTPUT
LATCH
D13
D0
1414 F01
Figure 1. Simplified Block Diagram
Signal-to-Noise Ratio
The signal-to-(noise + distortion) ratio [S/(N + D)] is the
ratio between the RMS amplitude of the fundamental input
frequency to the RMS amplitude of all other frequency
components at the A/D output. The output is band limited
to frequencies from above DC and below half the sampling
frequency. Figure 2a shows a typical spectral content with
a 2.2MHz sampling rate and a 100kHz input. The dynamic
performance is excellent for input frequencies up to and
beyond the Nyquist limit of 1.1MHz. (See Figure 2b)
0
SINAD = 80dB
SFDR = 96dB
fSAMPLE = 2.2MHz
fIN = 97.753kHz
–20
AMPLITUDE (dB)
During the conversion, the internal differential 14-bit
capacitive DAC output is sequenced by the SAR from the
most significant bit (MSB) to the least significant bit
(LSB). Referring to Figure 1, the AIN+ and AIN– inputs are
connected to the sample-and-hold capacitors (CSAMPLE)
during the acquire phase, and the comparator offset is
nulled by the zeroing switches. In this acquire phase, a
minimum delay of 70ns will provide enough time for the
sample-and-hold capacitors to acquire the analog signal.
During the convert phase the comparator zeroing switches
open, putting the comparator into compare mode. The
input switches connect the CSAMPLE capacitors to ground,
transferring the differential analog input charge onto the
summing junction. This input charge is successively compared with the binary-weighted charges supplied by the
differential capacitive DAC. Bit decisions are made by the
high speed comparator. At the end of a conversion, the
differential DAC output balances the AIN+ and AIN– input
charges. The SAR contents (a 14-bit data word) which
represents the difference of AIN+ and AIN– are loaded into
the 14-bit output latches.
ZEROING SWITCHES
HOLD
–40
–60
–80
DYNAMIC PERFORMANCE
–100
The LTC1414 has excellent high speed sampling capability. FFT (Fast Four Transform) test techniques are used to
test the ADC’s frequency response, distortion and noise at
the rated throughput. By applying a low distortion sine
wave and analyzing the digital output using an FFT algorithm, the ADC’s spectral content can be examined for
frequencies outside the fundamental. Figure 2 shows a
typical LTC1414 FFT plot.
–120
0
200
400
600
800
FREQUENCY (kHz)
1000
1414 F02a
Figure 2a. LTC1414 Nonaveraged, 2048 Point FFT,
Input Frequency = 100kHz
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LTC1414
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APPLICATIONS INFORMATION
0
–40
EFFECTIVE BITS
AMPLITUDE (dB)
–20
–60
–80
86
13
80
12
74
11
68
10
S/(N + D) (dB)
SINAD = 78dB
SFDR = 84dB
fSAMPLE = 2.2MHz
fIN = 997.949kHz
14
9
8
7
6
5
4
–100
3
fSAMPLE = 2.2MHz
2
–120
0
200
400
600
800
FREQUENCY (kHz)
1k
1000
10k
100k
1M
INPUT FREQUENCY (Hz)
10M
1414 TA02
1414 F02b
Figure 2b. LTC1414 2048 Point FFT,
Input Frequency = 1MHz
Figure 3. Effective Bits and Signal/(Noise + Distortion)
vs Input Frequency
0
–10
Effective Number of Bits
The effective number of bits (ENOBs) is a measurement of
the resolution of an ADC and is directly related to the
S/(N + D) by the equation:
ENOBS = [S/(N + D) – 1.76]/6.02
where S/(N + D) is expressed in dB. At the maximum
sampling rate of 2.2MHz the LTC1414 maintains near ideal
ENOBs up to the Nyquist input frequency of 1.1MHz. Refer
to Figure 3.
Total harmonic distortion (THD) is the ratio of the RMS
sum of all harmonics of the input signal to the fundamental
itself. The out-of-band harmonics alias into the frequency
band between DC and half the sampling frequency. THD is
expressed as:
2
2
2
V + V3 + V4 + … VN
THD = 20 log 2
V1
where V1 is the RMS amplitude of the fundamental frequency and V2 through VN are the amplitudes of the
second through Nth harmonics. THD vs input frequency is
shown in Figure 4. The LTC1414 has good distortion
performance up to the Nyquist frequency and beyond.
8
–30
–40
–50
THD
–60
–70
–80
2nd
–90
3rd
–100
1
100k
1M
10k
INPUT FREQUENCY (Hz)
10M
1414 F04
Figure 4. Distortion vs Input Frequency
Total Harmonic Distortion
2
DISTORTION (dB)
–20
Intermodulation Distortion
If the ADC input signal consists of more than one spectral
component, the ADC transfer function nonlinearity can
produce intermodulation distortion (IMD) in addition to
the THD. IMD is the change in one sinusoidal input caused
by the presence of another sinusoidal input at a different
frequency.
If two pure sine waves of frequencies fa and fb are applied
to the ADC input, nonlinearities in the ADC transfer function can create distortion products at the sum and difference frequencies of mfa ± nfb, where m and n = 0, 1, 2, 3
etc. For example, the 2nd order IMD terms include (fa ± fb).
If the two input sine waves are equal in magnitude, the
value (in dB) of the 2nd order IMD products can be
expressed by the following formula:
LTC1414
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APPLICATIONS INFORMATION
(
 amplitude at fa ± f b
IMD f a ± fb = 20log
 amplitude at fa

(
)
) 


0
fSAMPLE = 2.2MHz
fIN1 = 80.566kHz
fIN2 = 97.753kHz
AMPLITUDE (dB)
–20
–40
Driving the Analog Input
–60
–80
–100
–120
0
200
400
600
800
FREQUENCY (kHz)
1000
1414 F05a
Figure 5a. Intermodulation Distortion Plot
with Inputs at 80kHz and 97kHz
0
fSAMPLE = 2.2MHz
fIN1 = 970.019kHz
fIN2 = 1.492MHz
–20
AMPLITUDE (dB)
The full-linear bandwidth is the input frequency at which
the S/(N + D) has dropped to 74dB (12 effective bits). The
LTC1414 has been designed to optimize input bandwidth,
allowing the ADC to undersample input signals with frequencies above the converter’s Nyquist frequency. The
noise floor stays very low at high frequencies; S/(N + D)
becomes dominated by distortion at frequencies far beyond Nyquist.
–40
–60
–80
–100
The differential analog inputs of the LTC1414 are easy to
drive. The inputs may be driven differentially or as a singleended input (i.e., the AIN– input is grounded). The A IN+ and
AIN– inputs are sampled at the same instant. Any
unwanted signal that is common mode to both inputs will
be reduced by the common mode rejection of the sampleand-hold circuit. The inputs draw only one small current
spike while charging the sample-and-hold capacitors at
the end of conversion. During conversion, the analog
inputs draw only a small leakage current. If the source
impedance of the driving circuit is low then the LTC1414
inputs can be driven directly. As source impedance
increases so will acquisition time (see Figure 6). For
minimum acquisition time, with high source impedance, a
buffer amplifier should be used. The only requirement is
that the amplifier driving the analog input(s) must settle
after the small current spike before the next conversion
starts (settling time must be 70ns for full throughput rate).
–120
0
200
400
600
800
FREQUENCY (kHz)
1000
10
Figure 5b. Intermodulation Distortion Plot
with Input Signals of 1MHz and 1.5MHz
Peak Harmonic or Spurious Noise
The peak harmonic or spurious noise is the largest spectral component excluding the input signal and DC. This
value is expressed in dB relative to the RMS value of a fullscale input signal.
ACQUISITION TIME (µs)
1414 F05b
1
0.1
0.01
10
Full-Power and Full-Linear Bandwidth
The full-power bandwidth is that input frequency at which
the amplitude of the reconstructed fundamental is reduced by 3db for a full-scale input signal.
100
1k
10k
SOURCE RESISTANCE (Ω)
100k
1414 FO6
Figure 6. Acquisition Time vs Source Resistance
9
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APPLICATIONS INFORMATION
Choosing an Input Amplifier
AC Coupled Inputs
Choosing an input amplifier is easy if a few requirements
are taken into consideration. First, to limit the magnitude
of the voltage spike seen by the amplifier from charging
the sampling capacitor, choose an amplifier that has a low
output impedance (<100Ω) at the closed-loop bandwidth
frequency. For example, if an amplifier is used in a gain of
1 and has a unity-gain bandwidth of 50MHz, then the
output impedance at 50MHz must be less than 100Ω. The
second requirement is that the closed-loop bandwidth
must be greater than 40MHz to ensure adequate smallsignal settling for full throughput rate. If slower op amps
are used, more settling time can be provided by increasing
the time between conversions.
In applications where only the AC component of the analog
input is important, it may be desirable to AC couple the
input. This is easily accomplished by DC biasing the
LTC1414 analog input with a resistor to ground and using
a coupling capacitor to the input. Figure 7 shows a simple
AC coupled input circuit for the LTC1414 using only two
additional components. C1 is a 10µF ceramic capacitor
and R1 is a 1000Ω resistor to ground. R1 and C1 form a
highpass filter with a lower cut off frequency of 1/2π(C1)R1
or 15.9Hz.
C1
10µF
ANALOG INPUT
The best choice for an op amp to drive the LTC1414 will
depend on the application. Generally applications fall into
two categories: AC applications where dynamic specifications are most critical and time domain applications where
DC accuracy and settling time are most critical. The
following list is a summary of the op amps that are suitable
for driving the LTC1414. More detailed information is
available in the Linear Technology Databooks and on the
LinearViewTM CD-ROM.
LT®1223: 100MHz Video Current Feedback Amplifier.
6mA supply current. ±5V to ±15V supplies. Low noise.
Good for AC applications.
LT1227: 140MHz Video Current Feedback Amplifier. 10mA
supply current. ±5V to ±15V supplies. Low noise. Best for
AC applications.
LT1229/LT1230: Dual and Quad 100MHz Current Feedback Amplifiers. ±2V to ±15V supplies. Low noise. Good
AC specifications, 6mA supply current each amplifier.
LT1360: 50MHz Voltage Feedback Amplifier. 3.8mA supply current. Good AC and DC specs. ±5V to ±15V supplies.
70ns settling to 0.5LSB.
R1
1k
1
AIN+
2
AIN –
3
1µF
4
LTC1414
VREF
REFCOMP
10µF
5
AGND
LTC1414 • F07
Figure 7. AC Coupled Input
Differential Drive
In some applications the ADC drive circuitry is differential.
The differential drive can be applied directly to the LTC1414
without any special translation circuitry. Differential drive
can be advantageous at high frequencies (>1MHz) since it
provides improved THD and SFDR. Transformers can be
used to provide AC coupling, input scaling and single
ended to differential conversion as shown in Figure 8. The
resistor RS across the secondary will determine the input
impedance on the primary. The input impedance of the
primary RP will be related to the secondary load resistor RS
by the equation
RP = RS/n2
LT1363: 70MHz, 1000V/µs Op Amps. 6.3mA supply current. Good AC and DC specifications. 60ns settling to
0.5LSB.
For example, if a Minicircuits T4-6T transformer is used,
the turns ratio is 2; if RS is 200Ω then RP is equal to 50Ω.
LT1364/LT1365: Dual and Quad 70MHz, 1000V/µs Op
Amps. 6.3mA supply current per amplifier. 60ns settling
to 0.5LSB.
The center tap of the secondary will set the common
mode voltage and should be grounded for optimal AC
performance.
LinearView is a trademark of Linear Technology Corporation.
10
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APPLICATIONS INFORMATION
R1
50Ω
1:N
RP
ANALOG
INPUT
C1
500pF
RS
R2
50Ω
Input Range
1
AIN+
2
AIN –
3
1µF
4
LTC1414
VREF
REFCOMP
The ±2.5V input range of the LTC1414 is optimized for low
noise and low distortion. Most op amps also perform best
over this same range, allowing direct coupling to the
analog inputs and eliminating the need for special translation circuitry.
10µF
5
AGND
LTC1414 • F08
Figure 8. If a Transformer Coupled Input is Required,
this Circuit Provides a Simple Solution
Input Filtering
The noise and the distortion of the input amplifier and
other circuitry must be considered since they will add to
the LTC1414 noise and distortion. The small-signal bandwidth of the sample-and-hold circuit is 40MHz. Any noise
or distortion products that are present at the analog inputs
will be summed over this entire bandwidth. Noisy input
circuitry should be filtered prior to the analog inputs to
minimize noise. A simple 1-pole RC filter is sufficient for
many applications.
For example, Figure 9 shows a 500pF capacitor from AIN+
to ground and a 100Ω source resistor to limit the input
bandwidth to 3.2MHz. The 500pF capacitor also acts as a
charge reservoir for the input sample-and-hold and isolates the ADC input from sampling glitch-sensitive circuitry. High quality capacitors and resistors should be
used since poor quality components can add distortion.
NPO and silver mica type dielectric capacitors have excellent linearity. Carbon surface mount resistors can also
generate distortion from self heating and from damage
that may occur during soldering. Metal film surface mount
resistors are much less susceptible to both problems.
Some applications may require other input ranges. The
LTC1414 differential inputs and reference circuitry can
accommodate other input ranges often with little or no
additional circuitry. The following sections describe the
reference and input circuitry and how they affect the input
range.
Internal Reference
The LTC1414 has an on-chip, temperature compensated,
curvature corrected, bandgap reference that is factory
trimmed to 2.500V. It is connected internally to a reference
amplifier and is available at VREF (Pin 3), see Figure 10. A
2k resistor is in series with the output so that it can be
easily overdriven by an external reference or other circuitry. The reference amplifier multiplies the voltage at the
VREF pin by 1.625 to create the required internal reference
voltage. This provides buffering between the VREF pin and
the high speed capacitive DAC. The reference amplifier
compensation pin, REFCOMP (Pin 4) must be bypassed
with a capacitor to ground. The reference amplifier is
stable with capacitors of 1µF or greater. For the best noise
performance, a 10µF ceramic or 10µF tantalum in parallel
with a 0.1µF ceramic is recommended.
2.500V
R1
2k
3 VREF
BANDGAP
REFERENCE
+
100Ω
INPUT
500pF
1
AIN+
2
AIN –
3
4.0625V
4 REFCOMP
–
LTC1414
R2
40k
10µF
VREF
5 AGND
4
REFERENCE
AMP
R3
64k
LTC1414
REFCOMP
10µF
1414 F10
5
AGND
Figure 10. LTC1414 Reference Circuit
LTC1414 • F09
Figure 9. An RC Filter Reduces the ADC’s 40MHz
Bandwidth to 3.2MHz and Filters Out Wideband Noise
Which May Be Present in the Input Signal
11
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1
ANALOG INPUT
±2V TO ±3V
DIFFERENTIAL
80
COMMON MODE REJECTION (dB)
The VREF pin can be driven with a DAC or other means
shown in Figure 11. This is useful in applications where the
peak input signal amplitude may vary. The input span of
the ADC can then be adjusted to match the peak input
signal, maximizing the signal-to-noise ratio. The filtering
of the internal LTC1414 reference amplifier will limit the
bandwidth and settling time of this circuit. A settling time
of 5ms should be allowed after a reference adjustment.
AIN+
50
40
30
20
10
1k
2
3
4
10M
LTC1414 • F12
Figure 12. CMRR vs Input Frequency
VREF
The output is two’s complement binary with
1LSB = FS – (– FS)/16384 = 5V/16384 = 305.2µV.
REFCOMP
10µF
5
1M
10k
100k
INPUT FREQUENCY (Hz)
AIN–
AGND
1414 F11
Figure 11. Driving VREF with a DAC
Differential Inputs
The LTC1414 has a unique differential sample-and-hold
circuit that allows rail-to-rail inputs. The ADC will always
convert the difference of AIN+ – (AIN–) independent of the
common mode voltage. The common mode rejection
holds up to extremely high frequencies, see Figure 12. The
only requirement is that neither input can exceed the AVDD
or AVSS power supply voltages. Integral nonlinearity errors (INL) and differential nonlinearity errors (DNL) are
independent of the common mode voltage, however, the
bipolar zero error (BZE) will vary. The change in BZE is
typically less than 0.1% of the common mode voltage.
Dynamic performance is also affected by the common
mode voltage. THD will degrade as the inputs approach
either power supply rail, from –84dB with a common
mode of 0V to –75dB with a common mode of 2.5V
or –2.5V.
In applications where absolute accuracy is important,
offset and full-scale errors can be adjusted to zero. Offset
error must be adjusted before full-scale error. Figure 14
shows the extra components required for full-scale error
adjustment. Zero offset is achieved by adjusting the offset
applied to the AIN– input. For zero offset error apply
– 152µV (i.e., – 0.5LSB) at AIN+ and adjust the offset at the
AIN– input until the output code flickers between 0000
0000 0000 00 and 1111 1111 1111 11. For full-scale
adjustment, an input voltage of 2.499544V (FS – 1.5LSBs)
is applied to AIN+ and R2 is adjusted until the output
code flickers between 0111 1111 1111 10 and
0111 1111 1111 11.
011…111
011…110
011…101
OUTPUT CODE
2V TO 3V
60
0
LTC1414
LTC1450
70
000…000
111…111
100…010
100…001
Full-Scale and Offset Adjustment
Figure 13 shows the ideal input/output characteristics for
the LTC1414. The code transitions occur midway between
successive integer LSB values (i.e., – FS + 0.5LSB,
– FS + 1.5LSB, – FS + 2.5LSB,...FS – 2.5LSB, FS – 1.5LSB).
12
100…000
–(FS – 1LSB)
0
FS – 1LSB
INPUT RANGE
LTC1414 • F13
Figure 13. LTC1414 Transfer Characteristics
LTC1414
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APPLICATIONS INFORMATION
–5V
R3
24k
R1
50k
ANALOG INPUT
R4
100Ω
1
AIN+
2
AIN –
The LTC1414 has differential inputs to minimize noise
coupling. Common mode noise on the AIN+ and AIN–
inputs will be reflected by the input CMRR. The AIN– input
can be used as a ground sense for the AIN+ input; the
LTC1414 will hold and convert the difference voltage
between AIN+ and AIN–. The leads to AIN+ (Pin 1) and AIN–
(Pin 2) should be kept as short as possible. In applications
where this is not possible, the AIN+ and AIN– traces should
be run side by side to equalize coupling.
LTC1414
R5 R2
47k 50k
3
R6
24k
4
VREF
REFCOMP
10µF
5
AGND
LTC1414 • F14
Figure 14. Offset and Full-Scale Adjust Circuit
Board Layout and Bypassing
To obtain the best performance from the LTC1414, a
printed circuit board with a ground plane is required.
Layout for the printed circuit board should ensure that
digital and analog signal lines are separated as much as
possible. In particular, care should be taken not to run any
digital line alongside an analog signal line or underneath
the ADC. The analog input should be screened by AGND.
High quality tantalum and ceramic bypass capacitors
should be used at the VDD, VSS and VREF pins. Bypass
capacitors must be located as close to the pins as possible.
The traces connecting the pins and bypass capacitors
must be kept short and should be made as wide as
possible.
1
AIN+
AIN–
ANALOG
INPUT
CIRCUITRY
+
–
2
A single point analog ground separate from the logic
system ground should be established with an analog
ground plane at AGND (Pin 5, 27) or as close as possible
to the ADC (see Figure 8). The ADC’s DGND (Pin 23) and
all other analog grounds should be connected to this
single analog ground point. No other digital grounds
should be connected to this analog ground point. Low
impedance analog and digital power supply common
returns are essential to low noise operation of the ADC and
these traces should be as wide as possible. Excessive
capacitive loading on the ADC’s data output lines can
generate large transient currents on the ADC supplies
which may affect conversion results. In these cases, the
use of digital buffers is recommended to isolate the ADC
from the excessive loading.
EXAMPLE LAYOUT
Figures 16a, 16b, 16c and 16d show the schematic and
layout of an evaluation board. The layout demonstrates the
proper use of decoupling capacitors and ground plane
with a two layer printed circuit board.
DIGITAL
SYSTEM
LTC1414
REFCOMP
4
AGND
10µF
DVDD OVDD DGND OGND
AVDD
VSS
5, 27
26
10µF
28
22
21
23
14
10µF
ANALOG GROUND PLANE
1414 F15
Figure 15. Power Supply Grounding Practice
13
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APPLICATIONS INFORMATION
VSS
VCC
J3
5V
AGND
+
D2
SS12
DGND
J1
–5V
D1
SS12
C2
22µF
10V
+
J2
GND
VCC
VLOGIC
R14
20Ω
0.125W
C2
22µF
10V
+
C10
10µF
10V
VCC
C12
0.1µF
C14
0.1µF
C7
0.1µF
DGND
J9
JP3
JP2
J4
A+
R15
51Ω
R17
10k
R18
10k
JP4
J5
A–
C11
470pF
C4
0.1µF
VOUT
V + 7 U3
LT1363
2
–
6
3
+
8
V–
4 1
SO-8
V + 7 U1
LT1363
2
–
6
3
+
8
V–
4 1
DIP-8
(OPTIONAL)
R16
51Ω
C3
0.1µF
VSS
J10
VREF
C8
1µF
10V
J8
J7
CLK
C13
4.7µF
10V
VCC
VSS
R19
51Ω
DGND
C5
1µF
10V
C9
1µF
10V
U5
74HC574
B[00:13]
B00
B01
B02
B03
B04
B05
B08
U4
LTC1414CGN
1
2
3
4
25
24
23
22
21
28
26
27
5
14
AIN+ (MSB)D13
D12
AIN–
D11
VREF
REFCOMP D10
D9
BUSY
D8
CONVST
D7
DGND
D6
OVDD
D5
OVDD
D4
AVDD
D3
VSS
D2
AGND
D1
AGND
D0
OGND
6
7
8
9
10
11
12
13
15
16
17
18
19
20
B13
B12
B11
B10
B09
B08
B07
B06
B05
B04
B03
B02
B01
B00
1
11
2
3
4
5
6
7
8
9
0E
D0
D1
D2
D3
D4
D5
D6
D7
D[00:13]
Q0
Q1
Q2
Q3
Q4
Q5
Q6
Q7
19
18
17
16
15
14
13
12
D00
D01
D02
D03
D04
D05
D08
19
18
17
16
15
14
13
12
D07
D06
D09
D10
D11
D12
D13
U6
74HC574
B07
B06
B09
B10
B11
B12
B13
1
11
2
3
4
5
6
7
8
9
0E
D0
D1
D2
D3
D4
D5
D6
D7
Q0
Q1
Q2
Q3
Q4
Q5
Q6
Q7
D00
D01
D02
D03
D04
D05
D06
D07
D08
C15
1µF
10V
D09
U7G, HC14
VLOGIC
14
PWR
GND
D13
7
U7E, HC14
D11
11
D12
10
D13
DGND
DATA READY
NOTES: UNLESS OTHERWISE SPECIFIED
1. ALL RESISTOR VALUES IN OHMS, 1/10W, 5%
2. ALL CAPACITOR VALUES IN µF, 25V, 20% AND IN pF, 50V, 10%
13
12
U7F, HC14
R21
1k
C6
15pF
D13
9
8
U7D, HC14
1414 F16a
Figure 16a. Evaluation Circuit Schematic
14
D10
RDY
J6-13
D00
J6-14
D01
J6-11
D02
J6-12
D03
J6-9
D04
J6-10
D05
J6-7
D06
J6-8
D07
J6-5
D08
J6-6
D09
J6-3
D10
J6-4
D11
J6-1
D12
J6-2
D13
J6-15
D13
J6-16
RDY
J6-17
DGND
J6-18
DGND
HEADER
18-PIN
LTC1414
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APPLICATIONS INFORMATION
Figure 16b. Evaluation Circuit Board Component Side Silkscreen
15
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APPLICATIONS INFORMATION
Figure 16c. Evaluation Circuit Board Component Side Layout
16
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Figure 16d. Evaluation Circuit Board Solder Side Layout
17
LTC1414
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Digital Interface
The output data is updated at the end of the conversion as
BUSY rises. Output data is updated coincident with the
rising edge of BUSY. Data will be valid, and can be latched,
20ns after the rising edge of BUSY. Valid data can also be
latched with the falling edge of BUSY or with the rising
edge of CONVST. In the latter two cases the data latched
will be for the previous conversion.
The A/D converter has just one control input CONVST.
Data is output on 14-bit parallel bus. An additional output
BUSY indicates the converter status.
DIGITAL OUTPUTS
The parallel digital outputs of the LTC1414 are designed to
interface to TTL and CMOS logic. The output data is two’s
complement coded.
CONVST Drive Considerations
Timing jitter of the CONVST signal can adversely affect the
noise performance of the LTC1414 when the input signal
contains high slew rate components. The falling edge of
CONVST determines the sampling instant. Any uncertainty in this sampling instant will translate to voltage
noise when a fast changing input signal is being sampled.
For a full amplitude sinusoidal input, the relationship
between timing jitter (tjitter) and SNRj is
The output drivers have a separate power pin (OVDD) and
ground pin (OGND). This allows relatively noisy output
ground and the output supply bypass ground to be separated from the other ADC grounds. Additionally, the OVDD
pin may be driven by the supply of the logic that is being
driven. For example, the OVDD supply may be 3V while
LTC1414 DVDD and AVDD pins are 5V, allowing 3V logic to
be driven directly.
SNRj = 20log(1/2π • fIN • tjitter)
Care should be taken to not load the digital outputs with
excessive capacitance. Large capacitive loads result in
large charging currents which can cause conversion errors. It is recommended that the capacitive loading is kept
under 20pF. If it is not possible to keep the capacitance
low, a buffer or latch may be used to isolate the LTC1414
from the capacitive load.
where SNRj is the signal-to-jitter noise ratio.
Timing and Control
The internal clock is factory trimmed to achieve a typical
conversion time of 330ns and a maximum conversion
time over the full operating temperature range of 400ns.
No external adjustments are required. The guaranteed
maximum acquisition time is 100ns. In addition, a throughput time (acquisition + conversion) of 454ns and a minimum sampling rate of 2.2Msps is guaranteed.
The internal circuitry of the LTC1414 has been optimized
for ultralow jitter (typically 3ps RMS). The external clock
drive circuitry is equally important and must also have low
jitter to achieve low noise.
Internal Clock
The conversion start is controlled by the CONVST input.
The falling edge of CONVST will start a conversion. Once
initiated, it cannot be restarted until the conversion is
complete. Converter status is indicated by the BUSY
output. BUSY is low during a conversion.
tCONV
t4
t5
CONVST
t1
t3
BUSY
t2
DATA
DATA (N – 1)
DB13 TO DB0
DATA N
DB13 TO DB0
Figure 17. Timing Diagram
18
DATA (N + 1)
DB13 TO DB0
1414 F17
LTC1414
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PACKAGE DESCRIPTION
Dimensions in inches (millimeters) unless otherwise noted.
GN Package
28-Lead Plastic SSOP Narrow (0.150)
(LTC DWG # 05-08-1641)
0.386 – 0.393*
(9.804 – 9.982)
28 27 26 25 24 23 22 21 20 19 18 17 1615
0.229 – 0.244
(5.817 – 6.198)
0.150 – 0.157**
(3.810 – 3.988)
1
0.015 ± 0.004
× 45°
(0.38 ± 0.10)
0.0075 – 0.0098
(0.191 – 0.249)
0.033
(0.838)
REF
2 3
4
5 6
7
8
9 10 11 12 13 14
0.053 – 0.069
(1.351 – 1.748)
0.004 – 0.009
(0.102 – 0.249)
0° – 8° TYP
0.016 – 0.050
(0.406 – 1.270)
0.008 – 0.012
(0.203 – 0.305)
0.025
(0.635)
BSC
* DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
** DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
GN28 (SSOP) 0398
19
LTC1414
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TYPICAL APPLICATIO
2.2MHz, 14-Bit Sampling ADC
5V
DIFFERENTIAL ANALOG INPUT
–2.5V TO 2.5V
1
AIN+
AVDD
2
AIN–
AGND
3
VREF OUT
2.5V
4
1µF
10µF
5
REFCOMP
AGND
VSS
BUSY
CONVST
DGND
6 D13 (MSB)
7 D12
8 D11
9 D10
10 D9
11 D8
14-BIT
PARALLEL
BUS
12 D7
13 D6
14 OGND
27
–5V
10µF
10µF
LTC1414
VREF
28
DVDD
OVDD
D0
D1
D2
D3
D4
D5
26
25
24
23
22
0.1µF
5V
21
20
19
18
17
16
15
1414 TA03
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
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Nyquist Sampling, 150mW, 72dB SINAD
LTC1415
Single 5V, 12-Bit, 1.25Msps, ADC
Single Supply, 55mW Dissipation
LTC1416
Low Power, 14-Bit, 400ksps, ADC
±5V Supplies, 75mW Dissipation
LTC1417
Very Low Power, 14-Bit, 400ksps, ADC
20mW, 5V or ±5V Supply, Serial I/O in 16-Pin SSOP
LTC1418
Very Low Power, 14-Bit, 200ksps, ADC
15mW, 5V or ±5V Supply, Serial or Parallel I/O
LTC1419
Low Power, 14-Bit, 800ksps, ADC
True 14-Bit Linearity, 81.5dB SINAD, 150mW Dissipation
LTC1604
High Speed, 16-Bit, 333ksps, ADC
90dB SINAD, –100dB THD, 220mW Dissipation
LT1460
Micropower Precision Series Reference
0.075% Accuracy, 10ppm/°C Drift
20
Linear Technology Corporation
1414f LT/TP 0399 4K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com
 LINEAR TECHNOLOGY CORPORATION 1998