Datasheet Texas Instruments OPA690IDBVT
Manufacturer | Texas Instruments |
Series | OPA690 |
Part Number | OPA690IDBVT |
Wideband, Voltage Feedback Operational Amplifier With Disable 6-SOT-23 -40 to 85
Datasheets
OPA690 Wideband, Voltage-Feedback Operational Amplifier With Disable datasheet
PDF, 1.4 Mb, Revision: G, File published: Aug 10, 2016
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Status
Lifecycle Status | Active (Recommended for new designs) |
Manufacture's Sample Availability | Yes |
Packaging
Pin | 6 |
Package Type | DBV |
Industry STD Term | SOT-23 |
JEDEC Code | R-PDSO-G |
Package QTY | 250 |
Carrier | SMALL T&R |
Device Marking | OAEI |
Width (mm) | 1.6 |
Length (mm) | 2.9 |
Thickness (mm) | 1.2 |
Pitch (mm) | .95 |
Max Height (mm) | 1.45 |
Mechanical Data | Download |
Parametrics
2nd Harmonic | 68 dBc |
3rd Harmonic | 70 dBc |
@ MHz | 5 |
Acl, min spec gain | 1 V/V |
Additional Features | Shutdown |
Architecture | Bipolar,Voltage FB |
BW @ Acl | 500 MHz |
CMRR(Min) | 60 dB |
CMRR(Typ) | 65 dB |
GBW(Typ) | 500 MHz |
Input Bias Current(Max) | 10000000 pA |
Iq per channel(Max) | 5.8 mA |
Iq per channel(Typ) | 5.5 mA |
Number of Channels | 1 |
Offset Drift(Typ) | 10 uV/C |
Operating Temperature Range | -40 to 85 C |
Output Current(Typ) | 190 mA |
Package Group | SOT-23 |
Package Size: mm2:W x L | 6SOT-23: 8 mm2: 2.8 x 2.9(SOT-23) PKG |
Rail-to-Rail | No |
Rating | Catalog |
Slew Rate(Typ) | 1800 V/us |
Total Supply Voltage(Max) | 12 +5V=5, +/-5V=10 |
Total Supply Voltage(Min) | 5 +5V=5, +/-5V=10 |
Vn at 1kHz(Typ) | 5.5 nV/rtHz |
Vn at Flatband(Typ) | 5.5 nV/rtHz |
Vos (Offset Voltage @ 25C)(Max) | 4 mV |
Eco Plan
RoHS | Compliant |
Design Kits & Evaluation Modules
- Evaluation Modules & Boards: DEM-OPA-SOT-1A
Unpopulated PCB Compatible w/High Speed, Wide Bandwidth Op Amps in SOT(DBV) Pkg
Lifecycle Status: Active (Recommended for new designs) - Evaluation Modules & Boards: DEM-OPA-SO-1A
DEM-OPA-SO-1A Unpopulated PCB Compatible w/High Speed Wide Bandwidth Op Amps in 8-lead SOIC (D) Pkg
Lifecycle Status: Active (Recommended for new designs)
Application Notes
- A Numerical Solution to an Analog ProblemPDF, 210 Kb, File published: Apr 25, 2010
In order to derive a solution for an analog circuit problem, it is often useful to develop a model. This approach is generally accepted as developing an analytical model. However, finding the analytical solution is not always practical or possible as a result of higher-degree polynomials that require further resolution, or because of the time needed to develop the solution completely. In these sit - RLC Filter Design for ADC Interface Applications (Rev. A)PDF, 299 Kb, Revision: A, File published: May 13, 2015
As high performance Analog-to-Digital Converters (ADCs) continue to improve in their performance, the last stage interface from the final amplifier into the converter inputs becomes a critical element in the system design if the full converter dynamic range is desired. This application note describes the performance and design equations for a simple passive 2nd-order filter used successfully in AD - ADS5500, OPA695: PC Board Layout for Low Distortion High-Speed ADC DriversPDF, 273 Kb, File published: Apr 22, 2004
Once an analog-to-digital converter (ADC) and a driver/interface have been selected for a given application, the next step to achieving excellent performance is laying out the printed circuit board (PCB) that will support the application. This application report describes several techniques for optimizing a high-speed, 14-bit performance, differential driver PCB layout using a wideband operation - Measuring Board Parasitics in High-Speed Analog DesignPDF, 134 Kb, File published: Jul 7, 2003
Successful circuit designs using high-speed amplifiers can depend upon understanding and identifying parasitic PCB components. Simulating a design while including PCB parasitics can protect against unpleasant production surprises. This application report discusses an easy method for measuring parasitic components in a prototype or final PC board design by using a standard oscilloscope and low freq - Noise Analysis for High Speed Op Amps (Rev. A)PDF, 256 Kb, Revision: A, File published: Jan 17, 2005
As system bandwidths have increased an accurate estimate of the noise contribution for each element in the signal channel has become increasingly important. Many designers are not however particularly comfortable with the calculations required to predict the total noise for an op amp or in the conversions between the different descriptions of noise. Considerable inconsistency between manufactu
Model Line
Series: OPA690 (8)
Manufacturer's Classification
- Semiconductors > Amplifiers > Operational Amplifiers (Op Amps) > High-Speed Op Amps (>=50MHz)