This document describes an SFP+ DWDM 10G C-Band optical transceiver that operates at 10Gbps up to 80km on single mode fiber. It uses a DWDM EML laser transmitter, APD photodiode receiver, and built-in CDR. Key features include hot-pluggable SFP+ form factor, LC duplex optical interface, digital diagnostics, and operating temperature range of 0-70°C. The transceiver provides 10Gb Ethernet and 10GBase-ZR/ZW connectivity and is RoHS compliant.
This document summarizes the specifications of a BlueOptics SFP+ 10G 1550nm 40KM CDR optical transceiver module. It operates at 10Gbps over single mode fiber with a maximum link length of 40 kilometers. The module contains an EML laser transmitter, photodiode receiver, and built-in clock and data recovery circuits. It provides digital diagnostics for operating parameters via the SFP MSA interface.
This document provides specifications for the BlueOptics BO55J27610D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber up to 10km in length. The module uses a 1270nm DFB laser transmitter and 1330nm photodetector receiver. It complies with relevant industry standards and provides digital diagnostics for operating parameters.
This document provides specifications for an SFP+ CWDM optical transceiver operating at 8.5Gbps up to a distance of 10km over single mode fiber. The transceiver uses a DFB laser transmitter operating between 1270-1330nm and a PIN photodiode receiver. It supports multi-rate fiber channel and has hot-pluggable and RoHS compliant packaging. Diagnostic data on operating parameters can be accessed via the digital diagnostic interface.
This document provides specifications for an SFP+ CWDM optical transceiver operating at 8.5Gbps with a wavelength between 1470-1610nm and a maximum range of 80km. The transceiver uses an EML laser transmitter, APD receiver, and supports digital diagnostics monitoring via the SFF-8472 standard. It is compliant with SFP+ and telecom industry standards for performance, safety and manufacturing.
This document describes an SFP+ DWDM 10G C-Band optical transceiver that operates at 10Gbps up to 80km on single mode fiber. It uses a DWDM EML laser transmitter, APD photodiode receiver, and built-in CDR. Key features include hot-pluggable SFP+ form factor, LC duplex optical interface, digital diagnostics, and operating temperature range of 0-70°C. The transceiver provides 10Gb Ethernet and 10GBase-ZR/ZW connectivity and is RoHS compliant.
This document summarizes the specifications of a BlueOptics SFP+ 10G 1550nm 40KM CDR optical transceiver module. It operates at 10Gbps over single mode fiber with a maximum link length of 40 kilometers. The module contains an EML laser transmitter, photodiode receiver, and built-in clock and data recovery circuits. It provides digital diagnostics for operating parameters via the SFP MSA interface.
This document provides specifications for the BlueOptics BO55J27610D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber up to 10km in length. The module uses a 1270nm DFB laser transmitter and 1330nm photodetector receiver. It complies with relevant industry standards and provides digital diagnostics for operating parameters.
This document provides specifications for an SFP+ CWDM optical transceiver operating at 8.5Gbps up to a distance of 10km over single mode fiber. The transceiver uses a DFB laser transmitter operating between 1270-1330nm and a PIN photodiode receiver. It supports multi-rate fiber channel and has hot-pluggable and RoHS compliant packaging. Diagnostic data on operating parameters can be accessed via the digital diagnostic interface.
This document provides specifications for an SFP+ CWDM optical transceiver operating at 8.5Gbps with a wavelength between 1470-1610nm and a maximum range of 80km. The transceiver uses an EML laser transmitter, APD receiver, and supports digital diagnostics monitoring via the SFF-8472 standard. It is compliant with SFP+ and telecom industry standards for performance, safety and manufacturing.
This document provides specifications for an SFP+ CWDM optical transceiver module that operates at 8.5Gbps with a wavelength between 1470-1610nm and a maximum link length of 80km. The module uses an EML laser transmitter and APD receiver with digital diagnostics. It has an SFP+ form factor and complies with relevant interoperability standards.
This document provides information about a BlueOptics SFP+ transceiver module that operates at 10Gbps with wavelengths between 1470-1610nm and a maximum link length of 40km on single mode fiber. It supports SFP+ MSA compliance and provides digital diagnostics for real-time monitoring of supply voltage, laser bias current, output power, temperature and more.
This document provides information about the BO56HXX640DT2 SFP+ optical transceiver module. It is an 8.5Gbps transceiver that operates between 1470-1610nm on single mode fiber with a maximum link length of 40km. The document describes its specifications, features, applications, installation instructions and provides pinout, diagnostic and mechanical details.
This document provides specifications for a BlueOptics SFP+ CWDM 10G optical transceiver operating from 1270-1450nm and supporting transmission distances up to 60km. Key features include support for 10Gbps data rates and compliance with SFP+ and SFF-8472 standards. The transceiver uses an EML transmitter, APD diode, TIA, and digital diagnostics to transmit and receive optical signals within the specified wavelength range.
This document provides specifications for the BlueOptics BO55J33610D SFP+ 10G optical transceiver module. It supports 10Gbps data rates over single mode fiber up to 10km. The module uses a 1330nm DFB laser transmitter and 1270nm photodetector receiver. It complies with the SFP+ MSA and provides digital diagnostics for operating parameters.
This document provides specifications for a BlueOptics SFP+ transceiver module that operates at 10Gbps over single mode fiber with a wavelength between 1270-1450nm and a maximum link length of 40km. The module supports CWDM and includes a DFB laser transmitter, photodiode receiver, and digital diagnostics functionality.
This document provides specifications for the BlueOptics BO55J27660D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over distances of 60km on single mode fiber. Key features include a 1270nm laser transmitter, 1330nm receiver, digital diagnostics, and compliance with relevant telecom standards. The document details optical, electrical, mechanical and interface specifications to allow the module to be used in networking equipment.
This document provides specifications for a SFP+ CWDM 10G optical transceiver operating at 1470-1610nm wavelengths with a maximum range of 80km. The transceiver supports data rates up to 10Gbps and is compliant with relevant telecom standards. It provides digital diagnostics for real-time monitoring of operating parameters like power, temperature and bias current.
This document provides specifications for the BlueOptics BO55J27640D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber with a maximum link length of 40 kilometers. The module complies with relevant industry standards and provides digital diagnostics for real-time monitoring of operating parameters. It is hot-pluggable and operates from a single 3.3V power supply.
This document provides specifications for a BlueOptics SFP+ 10G 1550nm optical transceiver module that operates at 10Gbps up to 80km on single mode fiber. Key features include an EML laser transmitter, APD receiver, digital diagnostics monitoring, and compliance with SFP+ and RoHS standards. It has an operating temperature range of 0-70°C and is hot-pluggable.
This document provides information about a SFP+ CWDM 10G optical transceiver module operating at wavelengths between 1270-1450nm and supporting transmission distances up to 10km. The module supports data rates up to 10Gbps and complies with relevant industry standards. It provides digital diagnostic functions and real-time monitoring of parameters like supply voltage, laser current and temperature.
1) The document describes a BlueOptics SFP+ 10G 850nm 300M optical transceiver that supports data rates up to 10Gbps over multimode fiber with a link length of 300 meters.
2) It provides technical specifications for the transceiver's electrical interface, optical transmitter and receiver, pinout, EEPROM information, digital diagnostics, and mechanical dimensions.
3) The transceiver is compliant with relevant industry standards and provides features such as hot-pluggability, digital diagnostics, and a 5-year warranty.
This document provides specifications for the BlueOptics BO35J13610D SFP+ 10G 1310nm 10KM optical transceiver module. It is a high-performance module that supports 10Gbps transmission over 10km of single-mode fiber. The document describes its optical and electrical specifications, interfaces, diagnostic features, and mechanical dimensions. It also provides ordering information and contact details for the manufacturer.
This document describes an SFP+ optical transceiver module that provides:
- 10Gbps data transmission over single mode fiber up to 40km, using 1330nm laser transmission and 1270nm reception
- Compliance with relevant telecom standards for performance, safety and manufacturing
- Monitoring of operating parameters like power, current and temperature via digital diagnostics
This document provides information about a SFP+ optical transceiver module that operates at 10Gbps up to a distance of 10km on single mode fiber. Key details include:
- It operates in the 1270-1450nm wavelength range and supports 10G Ethernet and 10GBase applications.
- The transceiver module complies with SFP+ MSA standards and contains a laser transmitter, photodiode receiver, and digital diagnostic monitoring functions.
- It provides 10Gbps data rates with transmission distances up to 10km on single mode fiber. Operating temperature ranges are also specified.
This document provides specifications for the BlueOptics BO55J33660D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber up to 60km in length. The module uses a 1330nm DFB laser transmitter and 1270nm photodetector receiver. It complies with relevant industry standards and provides digital diagnostics for various operating parameters.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps up to a distance of 40km on single mode fiber. It provides digital diagnostic monitoring of parameters like supply voltage, laser bias current, temperatures and more. The transceiver is hot-pluggable and compliant with SFP+ and RoHS standards. It is designed for applications like 10G Ethernet, fiber channel and switch/router interfaces.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps over 2km of single-mode fiber. It provides digital diagnostic monitoring of parameters like power levels and temperature. The transceiver complies with relevant interoperability standards and safety regulations for optical components. It can be used for applications like Ethernet and Fibre Channel networking between switches and servers.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps over multimode fiber up to 220 meters. It provides high-speed data transmission and receives real-time diagnostic information on parameters like supply voltage, temperature, and optical power levels. The transceiver complies with relevant industry standards and safety certifications and comes with a 5-year warranty.
BlueOptics Bo67jxx680d 10gbase dwdm xfp transceiver c band 80 km singlemode l...CBO GmbH
This document provides specifications for a BlueOptics BO67JXX680D XFP DWDM 10G C-Band optical transceiver module that operates at 10Gbps up to 80km on single mode fiber. It lists the module's features such as an EML laser transmitter, APD photodetector, digital diagnostics support, and RoHS compliance. It also provides detailed optical and electrical parameters and pinout information.
This document provides specifications for an SFP+ CWDM optical transceiver module that operates at 8.5Gbps with a wavelength between 1470-1610nm and a maximum link length of 80km. The module uses an EML laser transmitter and APD receiver with digital diagnostics. It has an SFP+ form factor and complies with relevant interoperability standards.
This document provides information about a BlueOptics SFP+ transceiver module that operates at 10Gbps with wavelengths between 1470-1610nm and a maximum link length of 40km on single mode fiber. It supports SFP+ MSA compliance and provides digital diagnostics for real-time monitoring of supply voltage, laser bias current, output power, temperature and more.
This document provides information about the BO56HXX640DT2 SFP+ optical transceiver module. It is an 8.5Gbps transceiver that operates between 1470-1610nm on single mode fiber with a maximum link length of 40km. The document describes its specifications, features, applications, installation instructions and provides pinout, diagnostic and mechanical details.
This document provides specifications for a BlueOptics SFP+ CWDM 10G optical transceiver operating from 1270-1450nm and supporting transmission distances up to 60km. Key features include support for 10Gbps data rates and compliance with SFP+ and SFF-8472 standards. The transceiver uses an EML transmitter, APD diode, TIA, and digital diagnostics to transmit and receive optical signals within the specified wavelength range.
This document provides specifications for the BlueOptics BO55J33610D SFP+ 10G optical transceiver module. It supports 10Gbps data rates over single mode fiber up to 10km. The module uses a 1330nm DFB laser transmitter and 1270nm photodetector receiver. It complies with the SFP+ MSA and provides digital diagnostics for operating parameters.
This document provides specifications for a BlueOptics SFP+ transceiver module that operates at 10Gbps over single mode fiber with a wavelength between 1270-1450nm and a maximum link length of 40km. The module supports CWDM and includes a DFB laser transmitter, photodiode receiver, and digital diagnostics functionality.
This document provides specifications for the BlueOptics BO55J27660D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over distances of 60km on single mode fiber. Key features include a 1270nm laser transmitter, 1330nm receiver, digital diagnostics, and compliance with relevant telecom standards. The document details optical, electrical, mechanical and interface specifications to allow the module to be used in networking equipment.
This document provides specifications for a SFP+ CWDM 10G optical transceiver operating at 1470-1610nm wavelengths with a maximum range of 80km. The transceiver supports data rates up to 10Gbps and is compliant with relevant telecom standards. It provides digital diagnostics for real-time monitoring of operating parameters like power, temperature and bias current.
This document provides specifications for the BlueOptics BO55J27640D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber with a maximum link length of 40 kilometers. The module complies with relevant industry standards and provides digital diagnostics for real-time monitoring of operating parameters. It is hot-pluggable and operates from a single 3.3V power supply.
This document provides specifications for a BlueOptics SFP+ 10G 1550nm optical transceiver module that operates at 10Gbps up to 80km on single mode fiber. Key features include an EML laser transmitter, APD receiver, digital diagnostics monitoring, and compliance with SFP+ and RoHS standards. It has an operating temperature range of 0-70°C and is hot-pluggable.
This document provides information about a SFP+ CWDM 10G optical transceiver module operating at wavelengths between 1270-1450nm and supporting transmission distances up to 10km. The module supports data rates up to 10Gbps and complies with relevant industry standards. It provides digital diagnostic functions and real-time monitoring of parameters like supply voltage, laser current and temperature.
1) The document describes a BlueOptics SFP+ 10G 850nm 300M optical transceiver that supports data rates up to 10Gbps over multimode fiber with a link length of 300 meters.
2) It provides technical specifications for the transceiver's electrical interface, optical transmitter and receiver, pinout, EEPROM information, digital diagnostics, and mechanical dimensions.
3) The transceiver is compliant with relevant industry standards and provides features such as hot-pluggability, digital diagnostics, and a 5-year warranty.
This document provides specifications for the BlueOptics BO35J13610D SFP+ 10G 1310nm 10KM optical transceiver module. It is a high-performance module that supports 10Gbps transmission over 10km of single-mode fiber. The document describes its optical and electrical specifications, interfaces, diagnostic features, and mechanical dimensions. It also provides ordering information and contact details for the manufacturer.
This document describes an SFP+ optical transceiver module that provides:
- 10Gbps data transmission over single mode fiber up to 40km, using 1330nm laser transmission and 1270nm reception
- Compliance with relevant telecom standards for performance, safety and manufacturing
- Monitoring of operating parameters like power, current and temperature via digital diagnostics
This document provides information about a SFP+ optical transceiver module that operates at 10Gbps up to a distance of 10km on single mode fiber. Key details include:
- It operates in the 1270-1450nm wavelength range and supports 10G Ethernet and 10GBase applications.
- The transceiver module complies with SFP+ MSA standards and contains a laser transmitter, photodiode receiver, and digital diagnostic monitoring functions.
- It provides 10Gbps data rates with transmission distances up to 10km on single mode fiber. Operating temperature ranges are also specified.
This document provides specifications for the BlueOptics BO55J33660D SFP+ 10G optical transceiver module. It supports data rates up to 10Gbps over single mode fiber up to 60km in length. The module uses a 1330nm DFB laser transmitter and 1270nm photodetector receiver. It complies with relevant industry standards and provides digital diagnostics for various operating parameters.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps up to a distance of 40km on single mode fiber. It provides digital diagnostic monitoring of parameters like supply voltage, laser bias current, temperatures and more. The transceiver is hot-pluggable and compliant with SFP+ and RoHS standards. It is designed for applications like 10G Ethernet, fiber channel and switch/router interfaces.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps over 2km of single-mode fiber. It provides digital diagnostic monitoring of parameters like power levels and temperature. The transceiver complies with relevant interoperability standards and safety regulations for optical components. It can be used for applications like Ethernet and Fibre Channel networking between switches and servers.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps over multimode fiber up to 220 meters. It provides high-speed data transmission and receives real-time diagnostic information on parameters like supply voltage, temperature, and optical power levels. The transceiver complies with relevant industry standards and safety certifications and comes with a 5-year warranty.
BlueOptics Bo67jxx680d 10gbase dwdm xfp transceiver c band 80 km singlemode l...CBO GmbH
This document provides specifications for a BlueOptics BO67JXX680D XFP DWDM 10G C-Band optical transceiver module that operates at 10Gbps up to 80km on single mode fiber. It lists the module's features such as an EML laser transmitter, APD photodetector, digital diagnostics support, and RoHS compliance. It also provides detailed optical and electrical parameters and pinout information.
Bo32j15280d 10gbase-zr x2 transceiver 1550nm 80 kilometer singlemode sc-duple...CBO GmbH
The document describes a BlueOptics BO32J15280D X2 10G 1550nm single mode optical transceiver that supports data rates up to 10Gbps over 80km of single mode fiber. It provides key specifications such as an EML laser transmitter, PIN photo detector, XAUI electrical interface, hot-pluggable X2 footprint, and digital diagnostic monitoring of internal parameters. The transceiver complies with various telecom standards and has a 5-year warranty.
Bo77jxx280d 10gbase-dwdm x2_transceiver c-band 80 kilometer singlemode sc-dup...CBO GmbH
This document summarizes an optical transceiver module:
1. It is a 10G DWDM transceiver operating in the C-band with a range of 80km on single mode fiber.
2. It uses an EML laser transmitter and APD receiver and supports interfaces like 10G Ethernet, Fibre Channel, and SONET/SDH.
3. The transceiver provides digital diagnostics of parameters like supply voltage, laser power, and temperature.
BlueOptics Bo67hxx640d 2 4 8gbase dwdm xfp transceiver c band 40km singlemode...CBO GmbH
The document describes an XFP DWDM 8.5G C-Band optical transceiver module that operates at 8.5Gbps over 40km of single mode fiber. It contains an EML laser transmitter, PIN photodiode receiver, and digital diagnostic monitoring. The module complies with relevant interoperability standards and safety regulations, and offers various operating temperature ranges and wavelength channel options.
The document describes an X2 CWDM 10G optical transceiver operating at 1470-1610nm wavelengths for 40km single mode fiber links. It provides key specifications such as an EML laser transmitter, PIN photodetector, XAUI electrical interface, digital diagnostic monitoring and hot-pluggable small form factor.
This document describes an SFP+ 10G 1310nm optical transceiver that operates at 10Gbps over 10km of single-mode fiber. It provides high-speed data transmission and real-time diagnostic monitoring. The transceiver uses DFB laser transmission and PIN photodiode reception to comply with small form-factor pluggable standards for hot-pluggable optical modules.
The document describes a BO-X2-SFP+ X2 converter that allows the use of an SFP+ module in an X2 port. It has an XAUI electrical interface and is compliant with various industry standards. The converter provides real-time diagnostic information on operating conditions through its digital interface.
This document describes an SFP+ 10G 1550nm optical transceiver module that operates at 10Gbps over 40km of single mode fiber. It provides key specifications such as an EML laser transmitter, PIN photodetector receiver, hot-pluggable SFP+ form factor, LC duplex optical interface, and digital diagnostic monitoring functions as defined by SFF-8472. The transceiver is RoHS compliant and supports various industrial temperature ranges.
This document provides specifications for an SFP+ 8.5G 1310nm optical transceiver module that operates at up to 10Gbps over 10km of single-mode fiber. It includes detailed optical and electrical specifications, pinout diagrams, and compliance information. Key features are 8.5Gb/s data rate, 10km reach, hot-pluggable SFP+ form factor, and digital diagnostic monitoring. It is fully compatible with SFP+ and SFF-8472 industry standards.
This document provides specifications for the BlueOptics BO35G13610D SFP+ transceiver module. It supports data rates up to 6.25Gbps over 10km of single mode fiber. The module complies with relevant industry standards and provides digital diagnostics for voltage, current, temperature and optical power levels. It has an operating temperature range of 0-70°C and hot-pluggable SFP+ form factor.
This document describes an SFP+ optical transceiver that operates at 6.25Gbps over 2km of single mode fiber. It provides digital diagnostic monitoring and is compliant with relevant industry standards. Key features include an FP laser transmitter, PIN photodiode receiver, hot-pluggable SFP+ form factor, and operating temperature ranges from commercial to industrial.
This document provides specifications for the BlueOptics BO35H856S3D SFP+ optical transceiver module. It supports data rates up to 8.5Gbps over 300 meters of multimode fiber. The module includes a VCSEL laser transmitter, photodiode receiver, and digital diagnostics monitoring various parameters. It complies with relevant industry standards and has an operating temperature range of 0-70°C.
The document describes an SFP+ 10G 1550nm optical receiver module that operates at 10Gbps up to 80km on single mode fiber. It provides digital diagnostic functions for voltage, temperature, and received optical power. The module complies with SFP+ MSA standards and provides an SFP+ pluggable interface that supports applications such as Ethernet and fiber channel networks.
The document describes an XFP 10G 1310nm optical transceiver module that operates at 10Gbps over multi-mode fiber with a maximum link length of 220 meters. It provides key specifications such as an average output power of 0-0.5dBm, receiver sensitivity of -10.5dBm, wavelength range of 1270-1610nm, and operating temperature range of 0-70°C. The transceiver uses digital diagnostics to monitor real-time parameters and is compliant with RoHS and other industry standards.
This document describes an SFP 155M 1550nm optical transceiver module that operates at 155Mbps up to 120km on single mode fiber. It provides digital diagnostic functions and is compliant with RoHS and SFP MSA standards. Key features include a DFB laser transmitter, APD receiver, hot-pluggable SFP form factor, and operating temperature ranges from 0 to 85°C.
This document describes an XFP 10G 850nm 300M optical transceiver module from BlueOptics. It provides high-speed 10Gbps data transmission over 300 meters of multi-mode fiber. The module supports various networking standards and has features such as VCSEL laser transmitter, PIN photodetector, digital diagnostics, and RoHS compliance. It offers real-time monitoring of parameters like supply voltage, laser power, and temperature.
Similar to Blueoptics bo54jxx640d 10gbase-cwdm cdr sfp+ transceiver 1470nm - 1610nm 40km singlemode lc duplex 10 gigabit (12)
Blueoptics bo25k859s2d 40gbase-sr4 qsfp transceiver 4x850nm 150 meter multimo...CBO GmbH
This document describes a QSFP 40G 850nm 100M optical transceiver module. It provides high-level specifications including:
- It supports data rates up to 40Gbps over 100 meters of multi-mode fiber using 4 channels of VCSEL lasers and photodiodes.
- It complies with relevant QSFP and small form factor pluggable standards, and provides digital diagnostics over a 2-wire interface.
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Blueoptics bo01c152c0 1000base-zx gbic transceiver 1550nm 120 kilometer singl...CBO GmbH
This document provides information about a 1.25Gbps optical transceiver module that operates at 1550nm wavelengths and supports transmission distances of up to 120km. It has a hot-pluggable GBIC footprint and provides digital diagnostic monitoring of operating parameters like power, temperature and bias current. The transceiver uses a DFB laser for transmission and a PIN photodiode for reception, supporting Ethernet, Fiber Channel and other optical link applications.
This document describes a BiDi cSFP optical transceiver module that operates at 1.25Gbps over single mode fiber with a maximum range of 40km. The module uses a DFB laser transmitter operating at 1490nm and a PIN photodiode receiver operating at 1310nm. It provides digital diagnostic monitoring of operating parameters and is compliant with relevant industry standards for optical transceivers.
This document describes an SFP+ DWDM 10G C-Band optical transceiver that operates at 10Gbps up to 80km on single mode fiber. It provides high-speed data transmission and real-time diagnostic information. The transceiver complies with relevant interoperability standards and safety regulations.
This document describes an SFP+ DWDM 10G C-Band optical transceiver that operates at 10Gbps over single mode fiber with a range of 40 kilometers. It provides high-speed data transmission in compliance with telecommunications standards while offering features such as digital diagnostics, hot-pluggability, and RoHS compliance.
Taking AI to the Next Level in Manufacturing.pdfssuserfac0301
Read Taking AI to the Next Level in Manufacturing to gain insights on AI adoption in the manufacturing industry, such as:
1. How quickly AI is being implemented in manufacturing.
2. Which barriers stand in the way of AI adoption.
3. How data quality and governance form the backbone of AI.
4. Organizational processes and structures that may inhibit effective AI adoption.
6. Ideas and approaches to help build your organization's AI strategy.
How information systems are built or acquired puts information, which is what they should be about, in a secondary place. Our language adapted accordingly, and we no longer talk about information systems but applications. Applications evolved in a way to break data into diverse fragments, tightly coupled with applications and expensive to integrate. The result is technical debt, which is re-paid by taking even bigger "loans", resulting in an ever-increasing technical debt. Software engineering and procurement practices work in sync with market forces to maintain this trend. This talk demonstrates how natural this situation is. The question is: can something be done to reverse the trend?
"Choosing proper type of scaling", Olena SyrotaFwdays
Imagine an IoT processing system that is already quite mature and production-ready and for which client coverage is growing and scaling and performance aspects are life and death questions. The system has Redis, MongoDB, and stream processing based on ksqldb. In this talk, firstly, we will analyze scaling approaches and then select the proper ones for our system.
Essentials of Automations: Exploring Attributes & Automation ParametersSafe Software
Building automations in FME Flow can save time, money, and help businesses scale by eliminating data silos and providing data to stakeholders in real-time. One essential component to orchestrating complex automations is the use of attributes & automation parameters (both formerly known as “keys”). In fact, it’s unlikely you’ll ever build an Automation without using these components, but what exactly are they?
Attributes & automation parameters enable the automation author to pass data values from one automation component to the next. During this webinar, our FME Flow Specialists will cover leveraging the three types of these output attributes & parameters in FME Flow: Event, Custom, and Automation. As a bonus, they’ll also be making use of the Split-Merge Block functionality.
You’ll leave this webinar with a better understanding of how to maximize the potential of automations by making use of attributes & automation parameters, with the ultimate goal of setting your enterprise integration workflows up on autopilot.
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Key Takeaways:
Understanding the Customer Journey: Dr. Hill emphasized the importance of mapping and understanding the complete customer journey to identify touchpoints and opportunities for improvement.
Personalization Strategies: We discussed how to leverage data and insights to create personalized experiences that resonate with customers.
Technology Integration: Insights were shared on how inQuba’s advanced technology can streamline customer interactions and drive operational efficiency.
"Scaling RAG Applications to serve millions of users", Kevin GoedeckeFwdays
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zkStudyClub - LatticeFold: A Lattice-based Folding Scheme and its Application...Alex Pruden
Folding is a recent technique for building efficient recursive SNARKs. Several elegant folding protocols have been proposed, such as Nova, Supernova, Hypernova, Protostar, and others. However, all of them rely on an additively homomorphic commitment scheme based on discrete log, and are therefore not post-quantum secure. In this work we present LatticeFold, the first lattice-based folding protocol based on the Module SIS problem. This folding protocol naturally leads to an efficient recursive lattice-based SNARK and an efficient PCD scheme. LatticeFold supports folding low-degree relations, such as R1CS, as well as high-degree relations, such as CCS. The key challenge is to construct a secure folding protocol that works with the Ajtai commitment scheme. The difficulty, is ensuring that extracted witnesses are low norm through many rounds of folding. We present a novel technique using the sumcheck protocol to ensure that extracted witnesses are always low norm no matter how many rounds of folding are used. Our evaluation of the final proof system suggests that it is as performant as Hypernova, while providing post-quantum security.
Paper Link: https://eprint.iacr.org/2024/257
The Microsoft 365 Migration Tutorial For Beginner.pptxoperationspcvita
This presentation will help you understand the power of Microsoft 365. However, we have mentioned every productivity app included in Office 365. Additionally, we have suggested the migration situation related to Office 365 and how we can help you.
You can also read: https://www.systoolsgroup.com/updates/office-365-tenant-to-tenant-migration-step-by-step-complete-guide/
For the full video of this presentation, please visit: https://www.edge-ai-vision.com/2024/06/temporal-event-neural-networks-a-more-efficient-alternative-to-the-transformer-a-presentation-from-brainchip/
Chris Jones, Director of Product Management at BrainChip , presents the “Temporal Event Neural Networks: A More Efficient Alternative to the Transformer” tutorial at the May 2024 Embedded Vision Summit.
The expansion of AI services necessitates enhanced computational capabilities on edge devices. Temporal Event Neural Networks (TENNs), developed by BrainChip, represent a novel and highly efficient state-space network. TENNs demonstrate exceptional proficiency in handling multi-dimensional streaming data, facilitating advancements in object detection, action recognition, speech enhancement and language model/sequence generation. Through the utilization of polynomial-based continuous convolutions, TENNs streamline models, expedite training processes and significantly diminish memory requirements, achieving notable reductions of up to 50x in parameters and 5,000x in energy consumption compared to prevailing methodologies like transformers.
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The Department of Veteran Affairs (VA) invited Taylor Paschal, Knowledge & Information Management Consultant at Enterprise Knowledge, to speak at a Knowledge Management Lunch and Learn hosted on June 12, 2024. All Office of Administration staff were invited to attend and received professional development credit for participating in the voluntary event.
The objectives of the Lunch and Learn presentation were to:
- Review what KM ‘is’ and ‘isn’t’
- Understand the value of KM and the benefits of engaging
- Define and reflect on your “what’s in it for me?”
- Share actionable ways you can participate in Knowledge - - Capture & Transfer
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
Simplify your search for a reliable Python development partner! This list presents the top 10 trusted US providers offering comprehensive Python development services, ensuring your project's success from conception to completion.
Conversational agents, or chatbots, are increasingly used to access all sorts of services using natural language. While open-domain chatbots - like ChatGPT - can converse on any topic, task-oriented chatbots - the focus of this paper - are designed for specific tasks, like booking a flight, obtaining customer support, or setting an appointment. Like any other software, task-oriented chatbots need to be properly tested, usually by defining and executing test scenarios (i.e., sequences of user-chatbot interactions). However, there is currently a lack of methods to quantify the completeness and strength of such test scenarios, which can lead to low-quality tests, and hence to buggy chatbots.
To fill this gap, we propose adapting mutation testing (MuT) for task-oriented chatbots. To this end, we introduce a set of mutation operators that emulate faults in chatbot designs, an architecture that enables MuT on chatbots built using heterogeneous technologies, and a practical realisation as an Eclipse plugin. Moreover, we evaluate the applicability, effectiveness and efficiency of our approach on open-source chatbots, with promising results.
Have you ever been confused by the myriad of choices offered by AWS for hosting a website or an API?
Lambda, Elastic Beanstalk, Lightsail, Amplify, S3 (and more!) can each host websites + APIs. But which one should we choose?
Which one is cheapest? Which one is fastest? Which one will scale to meet our needs?
Join me in this session as we dive into each AWS hosting service to determine which one is best for your scenario and explain why!
Northern Engraving | Modern Metal Trim, Nameplates and Appliance PanelsNorthern Engraving
What began over 115 years ago as a supplier of precision gauges to the automotive industry has evolved into being an industry leader in the manufacture of product branding, automotive cockpit trim and decorative appliance trim. Value-added services include in-house Design, Engineering, Program Management, Test Lab and Tool Shops.
LF Energy Webinar: Carbon Data Specifications: Mechanisms to Improve Data Acc...DanBrown980551
This LF Energy webinar took place June 20, 2024. It featured:
-Alex Thornton, LF Energy
-Hallie Cramer, Google
-Daniel Roesler, UtilityAPI
-Henry Richardson, WattTime
In response to the urgency and scale required to effectively address climate change, open source solutions offer significant potential for driving innovation and progress. Currently, there is a growing demand for standardization and interoperability in energy data and modeling. Open source standards and specifications within the energy sector can also alleviate challenges associated with data fragmentation, transparency, and accessibility. At the same time, it is crucial to consider privacy and security concerns throughout the development of open source platforms.
This webinar will delve into the motivations behind establishing LF Energy’s Carbon Data Specification Consortium. It will provide an overview of the draft specifications and the ongoing progress made by the respective working groups.
Three primary specifications will be discussed:
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"$10 thousand per minute of downtime: architecture, queues, streaming and fin...Fwdays
Direct losses from downtime in 1 minute = $5-$10 thousand dollars. Reputation is priceless.
As part of the talk, we will consider the architectural strategies necessary for the development of highly loaded fintech solutions. We will focus on using queues and streaming to efficiently work and manage large amounts of data in real-time and to minimize latency.
We will focus special attention on the architectural patterns used in the design of the fintech system, microservices and event-driven architecture, which ensure scalability, fault tolerance, and consistency of the entire system.
Connector Corner: Seamlessly power UiPath Apps, GenAI with prebuilt connectorsDianaGray10
Join us to learn how UiPath Apps can directly and easily interact with prebuilt connectors via Integration Service--including Salesforce, ServiceNow, Open GenAI, and more.
The best part is you can achieve this without building a custom workflow! Say goodbye to the hassle of using separate automations to call APIs. By seamlessly integrating within App Studio, you can now easily streamline your workflow, while gaining direct access to our Connector Catalog of popular applications.
We’ll discuss and demo the benefits of UiPath Apps and connectors including:
Creating a compelling user experience for any software, without the limitations of APIs.
Accelerating the app creation process, saving time and effort
Enjoying high-performance CRUD (create, read, update, delete) operations, for
seamless data management.
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Russell Alfeche, Technology Leader, RPA at qBotic and UiPath MVP
Charlie Greenberg, host
3. BO54JXX640D
SFP+ CWDM 10G 1470 – 1610nm 40KM
CDR RoHS Compliant Optical Transceiver
- 3 -
1. Absolute Maximum Ratings
Parameter Symbol Min. Typ. Max. Unit
Storage Temperature Ts -40 85 ºC
Storage Ambient Humidity HA 5 95 %
2. Recommended Operating Conditions
Parameter Symbol Min. Typ. Max. Unit Note
Case Operating Temperature Tcase
0 70 BO54JXX640D
-10 80 ºC BO54JXX640DEX
-40 85 BO54JXX640DIN
Ambient Humidity HA 5 70 %
Transmission Distance 40 KM
Coupled Fiber Single mode fiber 9/125µm SMF
3. Electrical Interface Characteristics
Parameter Symbol Min. Typ. Max. Unit Note
Power Supply Voltage Vcc 3.14 3.3 3.46 V
Signal Input Voltage Icc 450 mA
Transmitter
Input differential impedance Rin 100 Ω 1
Single ended data input swing Vin,pp 180 1200 mV
Transmit Disable Voltage VD Vcc-1.3 Vcc V
Transmit Enable Voltage VEN Vee Vee+0.8 V 2
Transmit Disable Assert Time 10 µs
Receiver
Differential data output swing Vout,pp 300 850 mV 3
Data output rise time tr 38 Ps 4
Data output fall time tf 38 Ps 4
LOS Fault VLOS
fault
Vcc-1.3 VccHOST V 5
LOS Normal VLOS
norm
Vee Vee+0.8 V
5
Power Supply Rejection PSR 100 mVpp 6
Notes:
1. Internally AC coupled.
2. Or open circuit.
3. Into 100Ω differential termination.
4. 20-80%
5. LOS is an open collector output. Should be pulled up with 4.7KΩ on the host board.
6. All transceiver specifications are compliant with a power supply sinusoidal modulation of 20 Hz to 1.5 MHz
up to specified value through the power supply filtering network shown on page 23 of the Small Form -
factor Pluggable (SFP) Transceiver Multi Source Agreement (MSA), September 14, 2000.
4. BO54JXX640D
SFP+ CWDM 10G 1470 – 1610nm 40KM
CDR RoHS Compliant Optical Transceiver
- 4 -
4. Transmitter Specifications - Optical
Parameter Symbol Min. Typ. Max. Unit Note
Average Output Power POUT -1 3 dBm
Extinction Ratio ER 3.5 dB
Center Wavelength λC λ-6.5 λ λ+6.5 nm 1
Spectral Width (-20dB) σ 1 dB
SMSR 30
Transmitter and Dispersion Peanlty TDP 3 dB
RIN RIN -128 dB/Hz
Output Eye Mask Compliant with IEEE 0802.3ae
Notes:
1. λ is 1470,1490,1510,1530,1550,1570,1590 or 1610
5. Receiver Specifications - Optical
Parameter Symbol Min. Typ. Max. Unit Note
Input Optical Wavelength λIN 1270 1610 nm
Receiver Sensitivity PIN -15.8 dBM 1
Input Saturation Power (Overload) PSAT 0.5 dBm
LOS Assert PA -30 dBm
LOS De-assert PD -17 dBm
LOS Hysteresis PA-PD 0.5 dB
Notes:
1. Measured with 10Gb/s; BER =<10
-12
@PRBS=2
31
-1 non-return-to-zero.
6. SFP+ to Host Connector Pin Out
Pin Symbol Name / Description Note
1 VEET Transmitter Ground (Common with Receiver Ground) 1
2 TFAULT Transmitter Fault indication 2
3 TDIS Transmitter Disable 3
4 SDA 2-wire Serial Interface Data Line 4
5 SCL 2-wire Serial Interface Clock Line 4
6 MOD-ABS Module Absent. Grounded within the module 4
7 RS0 Rate Select 0 5
8 LOS Loss of Signal indication 6
9 RS1 No connection required 1
10 VEER Receiver Ground (Common with Transmitter Ground) 1
11 VEER Receiver Ground (Common with Transmitter Ground) 1
12 RD- Inv. Received Data Out
13 RD+ Received Data Out
14 VEER Receiver Ground (Common with Transmitter Ground) 1
15 VCCR Receiver Power Supply
16 VCCT Transmitter Power
17 VEET Transmitter Ground (Common with Receiver Ground) 1
18 TD+ Transmit Data In
19 TD- Inv. Transmit Data In
20 VEET Transmitter Ground (Common with Receiver Ground) 1
5. BO54JXX640D
SFP+ CWDM 10G 1470 – 1610nm 40KM
CDR RoHS Compliant Optical Transceiver
- 5 -
Notes:
1. Circuit ground is isolated from chassis ground.
2. Needs to be pulled up with 4.7k – 10kΩ on host board to a voltage from 2.0V to Vcc + 0.3V.
3. Tx_Disable is an input contact with a 4.7 kΩ to 10 kΩ pullup to VccT inside the module.
4. Mod_ABS is connected to VeeT or VeeR in the SFP+ module. The host may pull this contact up to
Vcc_Host with a resistor from 4.7 kΩ up to 10 kΩ.
5. RS1 are module inputs and are pulled low to VeeT with > 30 kΩ resistors in the module.
6. This is an open collector output, which should only be pulled with a resistor of 4.7k - 10kΩ. Pull up
voltage between 2.0V and 3.6V. Logic 1 indicates loss of signal; logic 0 indicates normal operation. The
output will be pulled to less than 0.8V.
Pinout of Connector Block on Host Board
7. EEPROM Information
The SFP MSA defines a 256-byte memory map in EEPROM describing the transceivers capabilities, standard
interfaces, manufacturer, and other information, which is accessible over a 2 wire serial interface at the 8-bit
address 1010000X (A0h).
Data
Address
Field Size
(Bytes)
Name of Field Contents (Hex) Description
0 1 Identifier XX Formfactor
1 1 Ext. Identifier XX
2 1 Connector XX
3-10 8 Transceiver XX XX XX XX XX XX XX XX Transmittter Code
11 1 Encoding XX
12 1 BR, Nominal XX Transceiver Speed
13 1 Reserved 00
14 1 Length (9μm) km XX Max. link length in KM
15 1 Length (9μm) 100m XX Max. link length in M
16 1 Length (50μm) 10m XX Max. link length in M
17 1 Length(62.5μm)10m XX Max. link length in M
18 1 Length (Copper) XX Max. link length in M
29 1 Reserved 00
30-35
16
Vendor name
XX XX XX XX XX XX XX XX
XX XX XX XX XX XX XX XX
Vendor name - OEM
36 1 Reserved 00
37-39 3 Vendor OUI XX XX XX
6. BO54JXX640D
SFP+ CWDM 10G 1470 – 1610nm 40KM
CDR RoHS Compliant Optical Transceiver
- 6 -
40-55
16
Vendor PN
XX XX XX XX XX XX XX XX
XX XX XX XX XX XX XX XX
Product Number -
depending on Part
56-59 4 Vendor rev XX XX XX XX Vendor revision
60-61 2 Wavelength XX XX Transceiver
Wavelength
62 1 Reserved 00
63 1
CC BASE
XX Checksum of bytes 0-
62
64-65 2 Options XX XX
66 1 BR, max XX
67 1 BR, min XX
68-83 16
Vendor SN
XX XX XX XX XX XX XX XX
XX XX XX XX XX XX XX XX
Part serial number
84-91 8 Vendor date code XX XX XX XX XX XX 20 20 Year, Month, Day
92 1 Diagnostic type XX Diagnostics
93 1 Enhanced option XX Diagnostics
94 1 SFF-8472 XX Diagnostics
95 1
CC_EXT
XX Checksum of bytes 64-
94
96-255 160 Vendor Specific
8. Digital Diagnostics / Digital Optical Monitoring
The transceiver provides serial ID memory contents and diagnostic information about the present
operating conditions by the 2-wire serial interface (SCL, SDA).
The diagnostic information with internal calibration or external calibration are all implemented,
including received power monitoring, transmitted power monitoring, bias current monitoring, supply
voltage monitoring and temperature monitoring.
9. Recommended Interface Circuit