01- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
02- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
03- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
04- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
05- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
06- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
07- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
08- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
09- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
10- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup.
11- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
02- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
03- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
04- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
05- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
06- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
07- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
08- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
09- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
100- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup.
01- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
02- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
03- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
04- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
05- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
06- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
07- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
08- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
09- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
10- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup.
11- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
02- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
03- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
04- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
05- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
06- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
07- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup. Facing this issue, I set out to design a DAQ system specifically for 10-inch racks—compact yet fully featured, offering the same level of performance as larger systems.
08- At the heart of this setup is the Raspberry Pi Compute Module 5, taking full advantage of the Raspberry ecosystem. The DAQ cards connect to a custom I/O board, making the entire system both a high-performance measurement device and an embedded PC. This integration allows for powerful data processing, seamless networking, and easy expansion, all in a compact form factor.
09- This project is still under development, and as with any first revision, there are bound to be challenges. Rev 1.0 is the initial step in refining the design, testing its capabilities, and identifying areas for improvement. While the core functionality is in place, real-world testing will reveal what works well and what needs adjustment. The goal is to iterate on this design, optimizing both hardware and software to make it as reliable and efficient as possible. Future revisions will focus on fine-tuning performance, improving signal integrity, and expanding compatibility with different test setups.
100- In 2024, I started building my own 10-inch rack for hardware testing. Designing PCBs is one thing, but testing and bringing them to life can be a long, exhausting process. I needed a reliable and compact data acquisition system to streamline my workflow, but most DAQ solutions on the market are built for 19-inch racks, which are far too bulky for my setup.
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| Ranking | Name | Answers |
|---|---|---|
| 1 | PCBWay Team | 9 |
| 2 | weslley ramos | 1 |
| 3 | Epishko Dmitry | 1 |
