# Amber

> open-source ARM-compatible 32-bit RISC processor

**Wikidata**: [Q4741217](https://www.wikidata.org/wiki/Q4741217)  
**Wikipedia**: [English](https://en.wikipedia.org/wiki/Amber_(processor))  
**Source**: https://4ort.xyz/entity/amber

## Summary
Amber is an open-source, ARM-compatible 32-bit RISC processor designed for open hardware applications. Its design documents are freely accessible and modifiable, making it a key project in the open-source hardware community.

## Key Facts
- Amber is an open-source ARM-compatible 32-bit RISC processor.
- It is classified as open hardware, meaning its design documents are publicly accessible and modifiable.
- The project is hosted on OpenCores (https://opencores.org/project/amber).
- Source code is available on GitHub (https://github.com/freecores/amber).
- It has Wikipedia entries in English and Hungarian.
- The project has a sitelink count of 2 on Wikidata.
- Amber is part of the broader open hardware movement, which includes 31 related sitelinks.

## FAQs
**What is Amber?**
Amber is an open-source 32-bit RISC processor compatible with ARM architectures, designed for open hardware applications.

**Where can I find Amber’s source code?**
The source code for Amber is available on GitHub at https://github.com/freecores/amber.

**Is Amber part of any larger initiatives?**
Yes, Amber is part of the open hardware movement, which promotes freely accessible and modifiable hardware designs.

**Does Amber have a Wikipedia page?**
Yes, Amber has Wikipedia entries in English and Hungarian under the title "Amber (processor)."

## Why It Matters
Amber represents a significant contribution to the open hardware movement by providing a freely accessible and modifiable 32-bit RISC processor design. Its compatibility with ARM architectures makes it valuable for educational, research, and embedded systems development, fostering innovation and collaboration in open-source hardware.

## Notable For
- Being an open-source ARM-compatible 32-bit RISC processor.
- Its inclusion in the open hardware movement, promoting accessibility and modifiability.
- Availability of source code on GitHub, facilitating community contributions.
- Presence on OpenCores, a platform for open-source hardware projects.

## Body
### Overview
Amber is an open-source 32-bit RISC processor designed to be compatible with ARM architectures. It is part of the open hardware movement, which emphasizes the accessibility and modifiability of hardware designs.

### Technical Specifications
- **Architecture**: 32-bit RISC processor.
- **Compatibility**: ARM-compatible.
- **Open Hardware**: Design documents are openly accessible and modifiable.

### Project Hosting and Source Code
- **OpenCores**: The project is hosted on OpenCores (https://opencores.org/project/amber), a platform dedicated to open-source hardware projects.
- **GitHub Repository**: The source code for Amber is available on GitHub (https://github.com/freecores/amber), allowing for community contributions and modifications.

### Documentation and Recognition
- **Wikipedia Entries**: Amber has Wikipedia entries in English and Hungarian, providing detailed information about the project.
- **Wikidata Description**: The project is described on Wikidata as an open-source ARM-compatible 32-bit RISC processor.
- **Sitelink Count**: Amber has a sitelink count of 2 on Wikidata, indicating its recognition and documentation across different platforms.

### Open Hardware Movement
Amber is part of the broader open hardware movement, which includes 31 related sitelinks. This movement promotes the idea of freely accessible and modifiable hardware designs, fostering innovation and collaboration in the hardware community.

### Community and Collaboration
The availability of Amber’s source code on GitHub and its hosting on OpenCores facilitate community contributions and modifications. This open approach allows developers and researchers to collaborate on improving and adapting the processor for various applications.

### Applications and Use Cases
Amber’s compatibility with ARM architectures makes it suitable for a wide range of applications, including educational projects, research initiatives, and embedded systems development. Its open-source nature encourages experimentation and innovation in hardware design.