diff --git a/documentation/asciidoc/computers/camera/rpicam_options_common.adoc b/documentation/asciidoc/computers/camera/rpicam_options_common.adoc index 2be1fe85d..d134d5782 100644 --- a/documentation/asciidoc/computers/camera/rpicam_options_common.adoc +++ b/documentation/asciidoc/computers/camera/rpicam_options_common.adoc @@ -184,12 +184,6 @@ Examples: Each accepts a single number defining the dimensions, in pixels, of the image displayed in the preview window. Does not effect the preview window dimensions, since images are resized to fit. Does not affect captured still images or videos. -==== `rawfull` - -Forces the sensor to capture images in full resolution mode regardless of xref:camera_software.adoc#width-and-height[requested output resolution]. Because larger resolutions require more resources, this can negatively impact framerate. When used with the HQ camera, each frame can take up to 18MB of space (compared with 5MB in 2×2 binned mode). Does not accept a value. - -For `rpicam-hello`, has no effect. - ==== `mode` Allows you to specify a camera mode in the following colon-separated format: `:::`. The system selects the closest available option for the sensor if there is not an exact match for a provided value. You can use the packed (`P`) or unpacked (`U`) packing formats. Impacts the format of stored videos and stills, but not the format of frames passed to the preview window. diff --git a/documentation/asciidoc/computers/config_txt/video.adoc b/documentation/asciidoc/computers/config_txt/video.adoc index 8690d22a9..b126c0ef2 100644 --- a/documentation/asciidoc/computers/config_txt/video.adoc +++ b/documentation/asciidoc/computers/config_txt/video.adoc @@ -6,7 +6,7 @@ To control HDMI settings, use the xref:configuration.adoc#set-resolution-and-rot ==== HDMI Pipeline for Raspberry Pi 4 -In order to support dual displays and modes up to 4k60, the Raspberry Pi 4 generates 2 output pixels for every clock cycle. +In order to support dual displays and modes up to 4Kp60, the Raspberry Pi 4 generates 2 output pixels for every clock cycle. Every HDMI mode has a list of timings that control all the parameters around sync pulse durations. These are typically defined via a pixel clock, and then a number of active pixels, a front porch, sync pulse, and back porch for each of the horizontal and vertical directions. diff --git a/documentation/asciidoc/computers/processors/bcm2712.adoc b/documentation/asciidoc/computers/processors/bcm2712.adoc index 9c7e97f6f..a34e1ceb8 100644 --- a/documentation/asciidoc/computers/processors/bcm2712.adoc +++ b/documentation/asciidoc/computers/processors/bcm2712.adoc @@ -2,7 +2,7 @@ Broadcom BCM2712 is the 16nm application processor at the heart of Raspberry Pi 5. It is the successor to the BCM2711 device used in Raspberry Pi 4, and shares many common architectural features with other devices in the BCM27xx family, used on earlier Raspberry Pi products. -Built around a quad-core Arm Cortex-A76 CPU cluster, clocked at up to 2.4GHz, with 512KB per-core L2 caches and a 2MB shared L3 cache, it integrates an improved 12-core VideoCore VII GPU; a hardware video scaler and HDMI controller capable of driving dual 4kp60 displays; and a Raspberry Pi-developed HEVC decoder and Image Signal Processor. A 32-bit LPDDR4X memory interface provides up to 17GB/s of memory bandwidth, while x1 and x4 PCI Express interfaces support high-bandwidth external peripherals; on Raspberry Pi 5 the latter is used to connect to the Raspberry Pi RP1 south bridge, which provides the bulk of the external-facing I/O functionality on the platform. +Built around a quad-core Arm Cortex-A76 CPU cluster, clocked at up to 2.4GHz, with 512KB per-core L2 caches and a 2MB shared L3 cache, it integrates an improved 12-core VideoCore VII GPU; a hardware video scaler and HDMI controller capable of driving dual 4Kp60 displays; and a Raspberry Pi-developed HEVC decoder and Image Signal Processor. A 32-bit LPDDR4X memory interface provides up to 17GB/s of memory bandwidth, while x1 and x4 PCI Express interfaces support high-bandwidth external peripherals; on Raspberry Pi 5 the latter is used to connect to the Raspberry Pi RP1 south bridge, which provides the bulk of the external-facing I/O functionality on the platform. Headline features include: diff --git a/documentation/asciidoc/microcontrollers/micropython/images/micropython_book_thumb.png b/documentation/asciidoc/microcontrollers/micropython/images/micropython_book_thumb.png deleted file mode 100644 index e7c347eef..000000000 Binary files a/documentation/asciidoc/microcontrollers/micropython/images/micropython_book_thumb.png and /dev/null differ diff --git a/documentation/asciidoc/microcontrollers/micropython/micropython-documentation.adoc b/documentation/asciidoc/microcontrollers/micropython/micropython-documentation.adoc index b814ca208..e0172ca86 100644 --- a/documentation/asciidoc/microcontrollers/micropython/micropython-documentation.adoc +++ b/documentation/asciidoc/microcontrollers/micropython/micropython-documentation.adoc @@ -7,11 +7,11 @@ https://datasheets.raspberrypi.com/picow/connecting-to-the-internet-with-pico-w. https://docs.micropython.org/en/latest/rp2/quickref.html[RP2 Quick Reference]:: The official documentation around the RP2040 port of MicroPython https://docs.micropython.org/en/latest/library/rp2.html[RP2 Library]:: The official documentation about the `rp2` module in MicroPython -[.booklink, booktype="buy", link=https://store.rpipress.cc/products/get-started-with-micropython-on-raspberry-pi-pico,image=image::images/micropython_book_thumb.png[]] - === Further reading -Check out https://store.rpipress.cc/collections/getting-started/products/get-started-with-micropython-on-raspberry-pi-pico[_Get Started with MicroPython on Raspberry Pi Pico_] to learn how to use the beginner-friendly language MicroPython to make your Raspberry Pi Pico interact with the world around it. Using these skills, you can create your own electro-mechanical projects, whether for fun or to make your life easier. +image::images/micropython_book.png[role="w40",float=right] + +Check out https://store.rpipress.cc/collections/getting-started/products/get-started-with-micropython-on-raspberry-pi-pico-2nd-edition[_Get Started with MicroPython on Raspberry Pi Pico_] to learn how to use the beginner-friendly language MicroPython to make your Raspberry Pi Pico interact with the world around it. Using these skills, you can create your own electro-mechanical projects, whether for fun or to make your life easier. * Set up your Raspberry Pi Pico and start using it * Start writing programs using MicroPython