Raspberry Pi Introduces New PCIe FFC Connector and HAT+ Standard Specifications, (from page 20221217.)
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Keywords
- Raspberry Pi
- HAT+
- PCIe FFC
- power consumption
- specifications
- Raspberry Pi 5
- HAT standard
Themes
- Raspberry Pi
- HAT+
- specifications
- PCIe FFC
- power consumption
Other
- Category: technology
- Type: blog post
Summary
Raspberry Pi has introduced two new specifications: one for the PCIe FFC connector and another for the HAT+ standard. The PCIe FFC connector specification includes details about its 16-pin 0.5mm pitch design, which features a single lane PCIe Gen 2 interface, and recommendations for compatible FFC cables. The HAT+ standard replaces the original HAT specification, allowing for greater flexibility in mechanical dimensions and ensuring compatibility with standby power states. Notably, HAT+ boards can stack and are electrically compatible with older Raspberry Pi models, although they require updated software. The specifications aim to enhance power management and simplify EEPROM content, with a final version expected next year. Discussions also highlight potential design challenges regarding the cooling solutions for Raspberry Pi 5.
Signals
| name |
description |
change |
10-year |
driving-force |
relevancy |
| HAT+ Standard Simplification |
The new HAT+ standard simplifies design rules for Raspberry Pi expansion boards. |
Shift from strict HAT specifications to a more flexible HAT+ standard for manufacturers. |
In ten years, we may see a diverse range of innovative Raspberry Pi add-ons due to simpler design rules. |
The need for manufacturers to create more versatile and varied add-ons for Raspberry Pi devices. |
4 |
| Power Management Modes |
Introduction of new power management modes for Raspberry Pi boards. |
Transition from WARM-STANDBY to STANDBY mode for lower power consumption in off state. |
Power management innovations could lead to more energy-efficient computing solutions in future devices. |
Growing emphasis on energy efficiency and sustainable technology in the electronics industry. |
4 |
| Emergence of M.2 HATs |
Development of M.2 HATs for Raspberry Pi 5 indicates a trend towards modular hardware solutions. |
Evolution from traditional HATs to modular M.2 HATs for enhanced functionality. |
In a decade, modular hardware could dominate the Raspberry Pi ecosystem, allowing easy upgrades. |
The increasing demand for customizable and upgradable computing solutions. |
5 |
| Community Engagement and Prototyping |
Active community experimentation with Raspberry Pi 5 hardware before official specifications were released. |
From a closed development process to more community-driven innovation and prototyping. |
In ten years, community-driven hardware development could become a standard practice in tech. |
The rise of maker culture and community collaboration in technology development. |
4 |
| Potential for New Form Factors |
Less prescriptive HAT dimensions allow for more diverse form factors in expansion boards. |
Shift from rigid design requirements to more adaptable board designs for Raspberry Pi. |
In a decade, we could see a wide array of unique and innovative form factors for Raspberry Pi add-ons. |
The desire for customization and innovation in hardware design. |
3 |
Concerns
| name |
description |
relevancy |
| Power Consumption in Standby Mode |
Potential confusion about power consumption levels in standby modes may lead to inefficient energy usage across devices. |
4 |
| Compatibility Issues of HAT+ Boards |
The need for updated software and firmware for compatibility with older models may create user confusion and potential malfunctions. |
3 |
| Physical Design Flexibility vs. Standardization |
Less prescriptive dimension requirements might lead to inconsistent designs that affect compatibility and user experience. |
3 |
| Incomplete Utility Updates for HAT+ Spec |
The pending updates for EEPROM utilities may hinder the functionality and adaptation of new HAT+ boards. |
3 |
| Cooling Accessibility |
Conflicting guidelines regarding the Raspberry Pi 5 active cooler might result in overheating issues if not properly addressed in HAT design. |
4 |
Behaviors
| name |
description |
relevancy |
| Adoption of New Standards |
Users and developers are quickly adopting the new Raspberry Pi HAT+ standard for expansion boards, indicating a shift towards more flexibility and simplicity in design. |
4 |
| Development of Custom Hardware |
Creators are experimenting with new hardware configurations, such as M.2 HATs for Raspberry Pi 5, before official specifications are released, showcasing innovation in the community. |
4 |
| Focus on Power Management |
There is a growing emphasis on power consumption and management, with users interested in utilizing the new STANDBY mode to minimize power usage when devices are off. |
5 |
| Flexibility in Design Dimensions |
The movement towards less prescriptive mechanical dimensions in HAT+ boards allows for more diverse and creative hardware designs within the Raspberry Pi ecosystem. |
3 |
| Community-Driven Hardware Solutions |
The community is actively working on adapting existing hardware, like the Radxa Penta SATA HAT, for compatibility with new Raspberry Pi models, indicating a collaborative innovation effort. |
4 |
Technologies
| name |
description |
relevancy |
| PCIe FFC Connector |
A new 16-pin FFC connector for Raspberry Pi 5 with a single lane PCIe interface, enabling better connectivity and expansion options. |
4 |
| Raspberry Pi HAT+ Standard |
An updated expansion board standard allowing for simpler designs, backward compatibility, and new power management features for Raspberry Pi. |
4 |
| STANDBY Power Modes |
New power management modes for Raspberry Pi that reduce power consumption in off states, enhancing energy efficiency. |
5 |
| M.2 HAT for Raspberry Pi 5 |
An add-on board utilizing the new M.2 interface for expanding storage capabilities of Raspberry Pi 5. |
4 |
Issues
| name |
description |
relevancy |
| Power Management in Standby Modes |
The introduction of the STANDBY power state could influence power consumption practices and design considerations for future Raspberry Pi applications. |
4 |
| HAT+ Standard Adoption |
The new HAT+ specification may lead to a shift in expansion board design and compatibility, impacting future Raspberry Pi projects. |
4 |
| Simplification of HAT EEPROM |
The new simpler EEPROM parameters could streamline development but may require adaptation from existing users. |
3 |
| Form Factor Flexibility |
Less prescriptive dimensions for HAT+ boards may encourage diverse form factors in hardware design, impacting future product offerings. |
3 |
| Compatibility Challenges with Older Models |
While HAT+ is backward-compatible, software and firmware updates may pose challenges for users with older Raspberry Pi models. |
3 |
| Cooling Solutions Design |
Conflicts regarding access to the Raspberry Pi 5 Active cooler may drive innovation in cooling solutions for future HAT designs. |
4 |