Datasheet Linear Technology LTC2411

Manufacturer	Linear Technology
Series	LTC2411

24-Bit No Latency Delta Sigma ADC with Differential Input and Reference in MSOP

Datasheets

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PDF, 598 Kb, Language: en, File uploaded: Aug 21, 2017, Pages: 42
24-Bit No Latency ∆Σ™ ADC with Differential Input and Reference in MSOP

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Prices

Packaging

	LTC2411CMS#PBF	LTC2411CMS#TRPBF	LTC2411IMS#PBF	LTC2411IMS#TRPBF
N	1	2	3	4
Package	MS-10 Package Outline Drawing	MS-10 Package Outline Drawing	MS-10 Package Outline Drawing	MS-10 Package Outline Drawing
Package Code	MS	MS	MS	MS
Package Index	05-08-1661	05-08-1661	05-08-1661	05-08-1661
Pin Count	10	10	10	10

Parametrics

Parameters / Models	LTC2411CMS#PBF	LTC2411CMS#TRPBF	LTC2411IMS#PBF	LTC2411IMS#TRPBF
ADC INL, LSB	33.5	33.5	33.5	33.5
ADCs	1	1	1	1
Architecture	Delta Sigma	Delta Sigma	Delta Sigma	Delta Sigma
Bipolar/Unipolar Input	Unipolar	Unipolar	Unipolar	Unipolar
Bits, bits	24	24	24	24
Number of Channels	1	1	1	1
DNL, LSB	1	1	1	1
Demo Boards	DC358A	DC358A	DC358A	DC358A
Design Tools	Linduino File	Linduino File	Linduino File	Linduino File
Export Control	no	no	no	no
Features	No Latency	No Latency	No Latency	No Latency
I/O	Serial SPI	Serial SPI	Serial SPI	Serial SPI
INL ppm, ppm	2	2	2	2
Input Drive	Differential	Differential	Differential	Differential
Input Span	В±VREF/2	В±VREF/2	В±VREF/2	В±VREF/2
Internal Reference	no	no	no	no
Operating Temperature Range, °C	0 to 70	0 to 70	-40 to 85	-40 to 85
Power, mW	1	1	1	1
Simultaneous	no	no	no	no
Speed, ksps	0.0075	0.0075	0.0075	0.0075
Supply Voltage Range	2.7V to 5.5V	2.7V to 5.5V	2.7V to 5.5V	2.7V to 5.5V

Eco Plan

	LTC2411CMS#PBF	LTC2411CMS#TRPBF	LTC2411IMS#PBF	LTC2411IMS#TRPBF
RoHS	Compliant	Compliant	Compliant	Compliant

Other Options

LTC2411-1

Application Notes

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Delta Sigma ADC Bridge Measurement Techniques &mdash AN96
PDF, 232 Kb, File published: Jan 17, 2005
AN96 features several applications that demonstrate how to take full advantage of Linear Technology's delta sigma ADCs when interfacing to sensors. In many cases, signal conditioning can be greatly simplified or eliminated completely. This note explains where it is appropriate to use amplifiers and how to optimize amplifier gain. Also included are discussions on measuring effective number of bits (ENOB) and the relationship to instrument performance, frequency response of delta sigma ADCs, and test techniques. C source code for all of the applications is included to aid firmware development.
Extract from the document
Application Note 96
January 2005
Delta Sigma ADC Bridge Measurement Techniques
Mark Thoren
Introduction In a typical 12-bit measurement system, the signal conditioning amplifier requires a very high gain in order to make
use of the full ADC input range. A sensor with a 10mV fullscale output requires a gain of 500 to use the full input
range of a typical 5V input ADC. A filter may be required to
reduce noise at the expense of settling time. Additional
difficulties arise when dealing with the large common
mode voltage typical of a bridge sensor. Most instrumentation amplifiers have a large discrepancy between the
typical CMRR and guaranteed minimum, which may require an additional trim. Sensors for pressure, load, temperature, acceleration and
many other physical quantities often take the form of a
Wheatstone bridge. These sensors can be extremely linear
and stable over time and temperature. However, most
things in nature are only linear if you donвЂ™t bend them too
much. In the case of a load cell, HookeвЂ™s law states that the
strain in a material is proportional to the applied stressвЂ”
as long as the stress is nowhere near the materialвЂ™s yield
point (the вЂњpoint of no returnвЂќ where the material is
permanently deformed). The consequence is that a load
cell based on a resistance strain gauge will have a very
small electrical outputвЂ”often only a few millivolts. In
spite of this, instruments with 100,000 counts of resolution and more are possible. This Application Note presents …

Articles

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No Latency Delta-Sigma ADC Techniques for Optimized Performance &mdash LT Journal
PDF, 239 Kb, File published: May 1, 2001
Extract from the document
DESIGN FEATURES Introduction Product Family Overview Linear TechnologyвЂ™s Delta-Sigma analog-to-digital converter product family
simplifies a variety of applications.
The productsвЂ™ ease-of-use and high
accuracy without the need for calibration, external clocks or complex
interfaces enables designers to rethink
their system architectures.
Although 24 bits may seem excessive to some, many designers find
significant advantages with these
higher resolution converters. One
such advantage is the elimination of
front-end amplification. This enables
direct digitization of many sensors
while removing problems associated
with front-end offset and gain errors
as well as simplifying tare adjustments. One misconception commonly
solved by designers using the
LTC2400 family is the relationship
between speed and resolution. Many
designers have found that higher
speed ADCs with averaging do not
meet the one-shot performance of the
LTC2400 family. The absolute accuracy of the LTC2400 family is
demonstrated using a bridge sensor …
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Using Bipolar Preamplifiers in an LTC2411-Based Correlated Double Sampling Scheme Produces a Noise Floor of Under 100nVRMS &mdash LT Journal
PDF, 160 Kb, File published: May 1, 2001
Extract from the document
DESIGN IDEAS Using Bipolar Preamplifiers in an
LTC2411-Based Correlated Double
Sampling Scheme Produces a Noise
by Derek Redmayne
Floor of Under 100nVRMS
Introduction
AC excitation. Putting preamplification in front of 24-bit delta sigma
converters such as the LTC2410 or
LTC2411 now uncovers the limitations of precision op amps. The most
serious of these limitations are offset
voltage drift, 1/f noise and thermocouple voltages that, in the presence
of turbulent airflow, produce noise.
The use of correlated double sampling, a close cousin of AC excitation,
circumvents most of the problems
associated with the use of a low noise
bipolar amplifier, but can often
become complicated, or can easily be
compromised to the extent that its
use is not worthwhile. 1/f noise are virtually eliminated.
Correlated double sampling has been
used in high end weigh scale applications for many years.
A low noise bipolar amplifier may
seem like the obvious choice as a …
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A New, Fully Differential, No Latency Delta-Sigma ADC Family &mdash LT Journal
PDF, 141 Kb, File published: Nov 1, 2000
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DESIGN INFORMATION A New, Fully Differential, No Latency
Delta-Sigma ADC Family by Michael K. Mayes
Introduction
In recent years, Linear Technology
has introduced a family of high resolution delta-sigma analog-to-digital
converters. Originating from the
LTC2400, this product family features high accuracy (10ppm total
error), ease of use (8-pins, on-chip
oscillator, no latency) and low drift
(user-transparent offset/full-scale
calibration). This product family
includes single-ended one-, two-, fourand eight-channel input devices with
user-selectable 50Hz or 60Hz linefrequency rejection.
A new family of differential-input
delta-sigma analog-to-digital converters is introduced here. These
converters offer features similar to
those of the previous family, with the
addition of differential input and differential reference. All devices offer
compatible timing and interface with
the original LTC2400, as well as transparent calibration, no latency, on-chip
oscillator and wide supply (2.7VвЂ“
5.5V), input and reference ranges.
The first part, the LTC2410, features 0.1ppm offset error, 2ppm INL, …

Model Line

Series: LTC2411 (4)

LTC2411CMS#PBF LTC2411CMS#TRPBF LTC2411IMS#PBF LTC2411IMS#TRPBF

Manufacturer's Classification

Data Conversion > Analog-to-Digital Converters (ADC) > Precision ADCs (Fs < 10Msps) > Single Channel ADCs