Introducing: Raspberry Pi 5!

Today, we’re delighted to announce the launch of Raspberry Pi 5, coming at the end of October. Priced at $60 for the 4GB variant, and $80 for its 8GB sibling, virtually every aspect of the platform has been upgraded, delivering a no-compromises user experience. Raspberry Pi 5 comes with new features, it’s over twice as fast as its predecessor, and it’s the first Raspberry Pi computer to feature silicon designed in‑house here in Cambridge, UK.

A Raspberry Pi 5, photographed corner-on, against a plain grey background.

Key features include:

  • 2.4GHz quad-core 64-bit Arm Cortex-A76 CPU
  • VideoCore VII GPU, supporting OpenGL ES 3.1, Vulkan 1.2
  • Dual 4Kp60 HDMI® display output
  • 4Kp60 HEVC decoder
  • Dual-band 802.11ac Wi-Fi®
  • Bluetooth 5.0 / Bluetooth Low Energy (BLE)
  • High-speed microSD card interface with SDR104 mode support
  • 2 × USB 3.0 ports, supporting simultaneous 5Gbps operation
  • 2 × USB 2.0 ports
  • Gigabit Ethernet, with PoE+ support (requires separate PoE+ HAT, coming soon)
  • 2 × 4-lane MIPI camera/display transceivers
  • PCIe 2.0 x1 interface for fast peripherals
  • Raspberry Pi standard 40-pin GPIO header
  • Real-time clock
  • Power button

In a break from recent tradition, we are announcing Raspberry Pi 5 before the product arrives on shelves. Units are available to pre-order today from many of our Approved Reseller partners, and we expect the first units to ship by the end of October.

Watch Eben do some talking about Raspberry Pi 5

We’re incredibly grateful to the community of makers and hackers who make Raspberry Pi what it is; you’ve been extraordinarily patient throughout the supply chain issues that have made our work so challenging over the last couple of years. We’d like to thank you: we’re going to ringfence all of the Raspberry Pi 5s we sell until at least the end of the year for single-unit sales to individuals, so you get the first bite of the cherry.

We’re also giving every print subscriber to The MagPi and HackSpace magazines a single-use code, giving them priority access to Raspberry Pi 5 hardware. Click those links to learn more about our Priority Boarding programme — and if you subscribe today, you can get your hands on a Priority Boarding pass too.

Between now and the end of October, we’ll be running a series of regular articles and videos, focusing on different aspects of the platform. Keep checking in here.

A little history

Way back in June 2019, we launched Raspberry Pi 4, the first true PC-class Raspberry Pi computer. With a quad-core Arm Cortex-A72 processor clocked at 1.5GHz, it was roughly forty times faster than the original Raspberry Pi model from 2012. In many ways the timing was perfect: in March the following year, schools closed, and millions of schoolchildren around the world were sent to study from home. Tens of thousands of them were able to rely on a Raspberry Pi 4 as their primary PC.

Watch Raspberry Pi 5 show you all of its bits without talking

In the four years since then, Raspberry Pi 4, and its derivatives Raspberry Pi 400 and Compute Module 4, have become firm favourites of enthusiasts, educators, and professional design engineers worldwide. Modern Raspberry Pi 4 computers run 20% faster than the launch variant, with a core clock speed of 1.8GHz. And, despite the well publicised challenges that have affected the electronics supply chain over the last two years, we’ve made and sold over 14 million units of Raspberry Pi 4 in that time.

But time doesn’t stand still, and neither does our community’s appetite for performance. And since 2016 — the era of Raspberry Pi 3 — we’ve been quietly working on a much more radical overhaul of the Raspberry Pi platform. Today, that effort bears fruit, with the launch of Raspberry Pi 5: compared to Raspberry Pi 4, we have between two and three times the CPU and GPU performance; roughly twice the memory and I/O bandwidth; and for the first time we have Raspberry Pi silicon on a flagship Raspberry Pi device.

New platform, new chipset

Three new chips, each designed specifically for the Raspberry Pi 5 program, come together to deliver a step change in performance.


Close-up photo of part of the Raspberry Pi 5 board, centring the metal shield over the BCM2712 chip, with laser etching identifying the chip.

BCM2712 is a new 16-nanometer application processor (AP) from Broadcom, derived from the 28-nanometer BCM2711 AP which powers Raspberry Pi 4, with numerous architectural enhancements. At its heart is a quad-core 64-bit Arm Cortex-A76 processor, clocked at 2.4GHz, with 512KB per-core L2 caches, and a 2MB shared L3 cache. Cortex-A76 is three microarchitectural generations beyond Cortex-A72, and offers both more instructions per clock (IPC) and lower energy per instruction. The combination of a newer core, a higher clock speed, and a smaller process geometry yields a much faster Raspberry Pi, and one that consumes much less power for a given workload.

Our newer, faster CPU is complemented by a newer, faster GPU: Broadcom’s VideoCore VII, developed here in Cambridge, with fully open source Mesa drivers from our friends at Igalia. An updated VideoCore hardware video scaler (HVS) is capable of driving two simultaneous 4Kp60 HDMI displays, up from single 4Kp60 or dual 4Kp30 on Raspberry Pi 4. A 4Kp60 HEVC decoder and a new Image Sensor Pipeline (ISP), both developed at Raspberry Pi, round out the multimedia subsystem. To keep the system supplied with memory bandwidth, we have a 32-bit LPDDR4X SDRAM subsystem, running at 4267MT/s, up from an effective 2000MT/s on Raspberry Pi 4.


Previous Raspberry Pi generations were built on a monolithic AP architecture: while some peripheral functions were provided by an external device (the Via Labs VL805 USB controller and hub on Raspberry Pi 4, and the Microchip LAN951x and LAN7515 USB hub and Ethernet controller chips on earlier products), substantially all of the I/O functions were integrated into the AP itself. Fairly early in the history of Raspberry Pi, we realised that as we migrated the AP to progressively newer process nodes, this approach would eventually become both technically and economically unsustainable.

Close-up photo of part of the Raspberry Pi 5 board, centring the RP1 chip, on which the Raspberry Pi logo and text identifying the chip are printed

Raspberry Pi 5, in contrast, is built on a disaggregated chiplet architecture. Here, only the major fast digital functions, the SD card interface (for board layout reasons), and the very fastest interfaces (SDRAM, HDMI, and PCI Express) are provided by the AP. All other I/O functions are offloaded to a separate I/O controller, implemented on an older, cheaper process node, and connected to the AP via PCI Express.

RP1 is our I/O controller for Raspberry Pi 5, designed by the same team at Raspberry Pi that delivered the RP2040 microcontroller, and implemented, like RP2040, on TSMC’s mature 40LP process. It provides two USB 3.0 and two USB 2.0 interfaces; a Gigabit Ethernet controller; two four-lane MIPI transceivers for camera and display; analogue video output; 3.3V general-purpose I/O (GPIO); and the usual collection of GPIO-multiplexed low-speed interfaces (UART, SPI, I2C, I2S, and PWM). A four-lane PCI Express 2.0 interface provides a 16Gb/s link back to BCM2712.

Under development since 2016, RP1 is by a good margin the longest-running, most complex, and (at $15 million) most expensive program we’ve ever undertaken here at Raspberry Pi. It has undergone substantial evolution over the years, as our projected requirements have changed: the C0 step used on Raspberry Pi 5 is the third major revision of the silicon. And while its interfaces differ in fine detail from those of BCM2711, they have been designed to be very similar from a functional perspective, ensuring a high degree of compatibility with earlier Raspberry Pi devices.


BCM2712 and RP1 are supported by the third new component of the chipset, the Renesas DA9091 “Gilmour” power-management IC (PMIC). This integrates eight separate switch-mode power supplies to generate the various voltages required by the board, including a quad-phase core supply, capable of providing 20 amps of current to power the Cortex-A76 cores and other digital logic in BCM2712.

Close-up photo of part of the Raspberry Pi 5 board, centring the DA9091 power-management IC, on which its name is printed

Like BCM2712, DA9091 is the product of a multi-year co-development effort. Working closely with the Renesas team in Edinburgh allowed us to produce a PMIC which is precisely tuned for our needs. And we were able to squeeze in two frequently requested features: a real-time clock (RTC), which can be powered by an external supercapacitor or a rechargeable lithium-manganese cell; and a PC-style power button, supporting hard and soft power-off and power-on events.

Two other elements of the chipset have been retained from Raspberry Pi 4. The Infineon CYW43455 combo chip provides dual-band 802.11ac Wi-Fi and Bluetooth 5.0 with Bluetooth Low-Energy (BLE); while the chip itself is unchanged, it is provided with a dedicated switched power supply rail for lower power consumption, and is connected to BCM2712 by an upgraded SDIO interface which supports DDR50 mode for higher potential throughput. As before, Ethernet connectivity is provided by a Broadcom BCM54213 Gigabit Ethernet PHY; this now sits at a jaunty 45-degree angle, a first for Raspberry Pi, and a source of enduring disappointment for orthogonal-layout enthusiast and CTO (Software) Gordon Hollingworth.

Form-factor evolution

On the outside, Raspberry Pi 5 closely resembles its predecessors. But, while retaining the overall credit-card-sized footprint, we’ve taken the opportunity to update some elements of the design, to align with the capabilities of the new chipset.

We’ve removed the four-pole composite video and analogue audio jack from the board. Composite video, now generated by RP1, is still available from a pair of 0.1”-spaced pads on the bottom edge of the board.

We now sport a pair of FPC connectors, in the space formerly occupied by the four-pole jack and camera connector. These are four-lane MIPI interfaces, using the same higher-density pinout found on various generations of Compute Module I/O board; and they are bi-directional (transceiver) interfaces, meaning that each one can connect either to a CSI-2 camera or to a DSI display. The space on the left of the board formerly occupied by the display connector now contains a smaller FPC connector which provides a single lane of PCI Express 2.0 connectivity for high-speed peripherals.

Close-up photo of part of the Raspberry Pi 5 board, centring the two FPC connectors, labelled CAM/DISP 0 and CAM/DISP 1

The Gigabit Ethernet jack has returned to its classic position in the bottom right corner of the board, after a brief sojourn in the top right on Raspberry Pi 4. And it’s brought with it the four-pin PoE connector, simplifying the board layout at the cost of a compatibility break with our existing PoE and PoE+ HATs.

Finally, we’ve grown a pair of mounting holes for a heatsink, as well as JST connectors for the RTC battery (two pins), Arm debug and UART (three pins), and fan with PWM control and tacho feedback (four pins).

Designed in Cambridge, manufactured in Wales

Like all flagship Raspberry Pi products, Raspberry Pi 5 is built at the Sony UK Technology Centre in Pencoed, South Wales. We have been working with Sony since the launch of the first Raspberry Pi computer in 2012, and we’re firm believers in the benefits of manufacturing our products within a few hours’ drive of our engineering design centre in Cambridge: a decade of frequent interaction with the Sony team has helped us understand how to design products that can be built reliably, cheaply, and at massive scale.

Close-up photo of a corner of the Raspberry Pi 5 box, centred on a Welsh flag icon (red dragon rampant on a grey field against a white sky) beside the words "Made in the UK".

Raspberry Pi 5 marks the introduction of a number of manufacturing innovations. One of these is intrusive reflow for connectors, which improves the mechanical quality of the product, increases throughput, and eliminates the costly and energy-intensive selective- or wave-solder process from the production flow. Others include fully routed panel singulation for cleaner board edges, and a new approach to production test inspired by our experiences testing our RP2040 microcontroller at scale.

Accessories, accessories, accessories

Every new flagship Raspberry Pi product is accompanied by new accessories, and Raspberry Pi 5 is no exception. Layout changes, new interfaces, and much higher peak performance (and a smaller increase in peak power consumption) have led us to redesign some existing accessories, and to develop some entirely new ones.


The updated case for Raspberry Pi 5, priced at $10, builds on the aesthetic of its Raspberry Pi 4 predecessor, but adds a host of new usability and thermal-management features.

An integrated 2.79 (max) CFM fan, with fluid dynamic bearings selected for low noise and an extended operating lifetime, connects to the four-pin JST connector on Raspberry Pi 5 to provide temperature‑controlled cooling. Air is drawn in through a 360‑degree slot under the lid, blown over a heatsink attached to the BCM2712 AP, and exhausted through connector apertures and vents in the base.

The Raspberry Pi Case for Raspberry Pi 5, showing its red base, the fan assembly with a white frame floating above it, and the white lid floating above that

We’ve lengthened the case, and tweaked the retention features, to make it possible to insert the Raspberry Pi 5 board without removing the SD card. And by removing the top of the case, it is now possible to stack multiple cases, as well as to mount HATs on top of the fan, using spacers and GPIO header extensions.

Like all our plastic products, the new case is manufactured by our friends at T-Zero, in the West Midlands, UK.

Active Cooler

Raspberry Pi 5 has been designed to handle typical client workloads, uncased, with no active cooling. Users who wish to use the board uncased under continuous heavy load, without throttling, have the option of adding a $5 Active Cooler. This attaches to the board via two new mounting holes, and connects to the same four-pin JST connector as the case fan.

The Raspberry Pi Active Cooler mounted on a Raspberry Pi 5. The blower, heatsink, and wires connecting to the Raspberry Pi's four-pin JST connector are visible.

A radial blower, again selected for low noise and extended operating lifetime, pushes air through an extruded and milled aluminium heatsink. Both the case and the Active Cooler are able to keep Raspberry Pi 5 well below the thermal throttle point for typical ambient temperatures and worst-case loads. The cooling performance of the Active Cooler is somewhat superior, making it particularly suitable for overclockers.

27W USB-C Power Supply

Raspberry Pi 5 consumes significantly less power, and runs significantly cooler, than Raspberry Pi 4 when running an identical workload. However, the much higher performance ceiling means that for the most intensive workloads, and in particular for pathological “power virus” workloads, peak power consumption increases to around 12W, versus 8W for Raspberry Pi 4.

When using a standard 5V, 3A (15W) USB-C power adapter with Raspberry Pi 5, by default we must limit downstream USB current to 600mA to ensure that we have sufficient margin to support these workloads. This is lower than the 1.2A limit on Raspberry Pi 4, though generally still sufficient to drive mice, keyboards, and other low‑power peripherals.

The white 3-pin UK variant of the new Raspberry Pi 27W USB-C Power Supply, pictured with the cable tightly wrapped with a cable tie and the pins facing towards the viewer

For users who wish to drive high-power peripherals like hard drives and SSDs while retaining margin for peak workloads, we are offering a $12 USB-C power adapter which supports a 5V, 5A (25W) operating mode. If the Raspberry Pi 5 firmware detects this supply, it increases the USB current limit to 1.6A, providing 5W of extra power for downstream USB devices and 5W of extra on-board power budget: a boon for those of you who want to experiment with overclocking your Raspberry Pi 5.

It should be noted that users have the option to override the current limit, specifying the higher value even when using a 3A adapter. In our testing, we have found that in this mode Raspberry Pi 5 functions perfectly well with typical configurations of higher-power USB devices, and all but the most pathological workloads.

Camera and display cables

The new, higher-density pinout of the MIPI connectors means that an adapter is required to connect our own cameras and displays, and third-party products, to Raspberry Pi 5.

To support existing camera and display owners, we are offering FPC camera and display cables, which convert from the higher-density format (now referred to as “mini”) to the older lower-density format (now referred to as “standard”). These cables are available in 200mm, 300mm, and 500mm lengths, priced at $1, $2, and $3 respectively.

Two orange cables crossed at one far end lying flat on a plain grey background. White writing on the each cable says "Raspberry Pi Display Cable Standard Mini 200mm" with a Raspberry Pi logo in white and other legal safety logos in white

Camera Module 3, the High-Quality Camera, the Global Shutter Camera, and the Touchscreen Display will all ship with both a standard-to-standard and a 200mm mini-to-standard cable.


From early 2024, we will be offering a new PoE+ HAT. This supports the new location for the four-pin PoE header, and has an L-shaped form factor which allows it to sit inside the Raspberry Pi 5 case without interfering mechanically or disrupting airflow.

A visibly hand-soldered prototype of the L-shaped Raspberry Pi PoE+ HAT for Raspberry Pi 5
Prototype PoE+ HAT. We don’t know yet what the production version will look like, but we do know that it won’t look like this.

The new PoE+ HAT integrates a planar transformer into the PCB layout, and utilises an optimised flyback converter architecture to sustain high efficiency across the whole zero to 25W range of output powers.

M.2 HATs

One of the most exciting additions to the Raspberry Pi 5 feature set is the single-lane PCI Express 2.0 interface. Intended to support fast peripherals, it is exposed on a 16-pin, 0.5mm pitch FPC connector on the left-hand side of the board.

From early 2024, we will be offering a pair of mechanical adapter boards which convert between this connector and a subset of the M.2 standard, allowing users to attach NVMe SSDs and other M.2-format accessories. The first, which conforms to the standard HAT form factor, is intended for mounting larger devices. The second, which shares the L-shaped form factor of the new PoE+ HAT, supports mounting 2230- and 2242-format devices inside the Raspberry Pi 5 case.

Prototype of the larger (standard HAT form factor) M.2 HAT, mounted on a Raspberry Pi 5
Prototype M.2 HAT. Final hardware will not look like this.

Raspberry Pi Beginner’s Guide, 5th Edition

Sporting a brand-new look and feel, and priced at RRP £19.99 ($24.99), this new edition of our bestselling Raspberry Pi Beginner’s Guide is the definitive manual for Raspberry Pi computers and accessories. It has been comprehensively updated to cover Raspberry Pi 5, and the upcoming release of Raspberry Pi OS based on Debian Bookworm.

RTC battery

RTC coin cell connected by red and black jumper wires to a two-pin JST plug

Last, but very much not least, we have sourced a Panasonic lithium manganese rechargeable coin cell, with a pre-fitted two-pin JST plug and an adhesive mounting pad. This is priced at $5, and is suitable for powering the Raspberry Pi 5 real-time clock (RTC) when the main power supply is disconnected.

A newer, better Raspberry Pi OS

In parallel with the final stages of the Raspberry Pi 5 programme, our software team has been busy developing a new version of Raspberry Pi OS, the official first-party operating system for Raspberry Pi devices. This is based on the most recent release of Debian (and its derivative Raspbian), codenamed “Bookworm”, and incorporates numerous enhancements, notably the transition from X11 to the Wayfire Wayland compositor on Raspberry Pi 4 and 5.

Raspberry Pi OS will launch in mid-October, and will be the sole supported first-party operating system for Raspberry Pi 5. Keep checking back here: we’ll be telling you some more about the new OS, and you’ll be able to download it shortly before Raspberry Pi 5 arrives on the shelves in late October.


Bringing Raspberry Pi 5 to life has been a seven-year, $25 million endeavour, involving tens of organisations and hundreds of individuals. A non-exhaustive list of those who have contributed to Raspberry Pi 5, and its constituent silicon programs, is here.

Leave a Reply

Your email address will not be published. Required fields are marked *

This site uses Akismet to reduce spam. Learn how your comment data is processed.

Server Status

Aradippou Chat Larnaca Nicosia

Chat Links

Official Links.


Alternative Mirror Links.

1. KiwiIRC 1.
2. KiwiIRC 2.

Other Web Clients.

1. IrcCloud.

Recent Posts

Related Posts:


Follow me on Mastodon

Super Club Radio

Mighty Deals


CyIRC Tweets