Listado de la etiqueta: Raspberry


The Raspberry Pi is the SBC used to host an operating system. The Raspberry Pi has no internal memory, so we have to connect the storage devices like USB, micro SD card, or the SSD(Solid State Drive). The SSD drives are fast, durable, and have no sound because these drives have integrated circuit assemblies on a PCB board to store the data.

Because of their high speeds, it is recommended to use the SSD drives with the Raspberry Pi to host the operating system and for storage purposes. In this write-up, we will explore the top five SSD drives which can be used with the Raspberry Pi 4.

Best SSDs for Raspberry Pi 4

Nowadays, for better performance and speed, the trend of using hard drives is shifting from HDDs to SSDs. The best SSDs which can be used with the Raspberry Pi 4 are discussed below in detail.

1 : SAMSUNG 870 EVO SATA III SSD

This SSD is manufactured by Samsung and is recommended to you if you are concerned with large storage memory with high performance. This SSD is available from 250 GB to 4 TB, moreover,  the reading and writing speed of this SSD is 560 MB/s and 530 MB/s, respectively. You can use this SSD for different tasks like the 8k video processing. The necessary software is pre-installed on the SSD like a drive health check, performance optimization, and the encrypted drive.

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2 : SAMSUNG 870 QVO SATA III SSD

This is another recommended SSD for Raspberry Pi that is available up to 8 TB, and so now users can enjoy 8 TB storage without compromising on the performance. It also supports the TurboWrite, which accelerates the writing speed and maintains a long variable buffer with high performance. If we consider the groundbreaking capacity of the 870 QVO SATA II, then we can say that it is being improved from 1,440 TBW to up to 2,880 TBW.

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3 : SanDisk 3D SATA III SSD

The users who are working on the development of different software, as well as the ones who are using the Raspberry Pi for playing games, are suggested to go for the Sandisk 3D SATA III because of its high performance. The trascendental features of this drive are the SATA III 6 GB/s interfaces, nCache 2.0 Technology, and the support of 3D NAND Technology.

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4 : Crucial MX500 SSD

Another SSD drive that is available in sizes up to 500 GB was released by the Crucial. If we talk about the physical features of the SSD then we can say that it has a form multiplicador of 2.5″/7mm, and reading and writing speeds are Up to 560 MB/s and 510 MB/s respectively. The unique features of this drive are it contains the AES-256 encryption and Opal 2.0 for securing the sensitive data stored on the SSD, moreover, for backing up your stored data on the SSD, it provides the Acronis True Image software.

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5 : ORICO GV100 SSD

This SSD is made up of Aluminum alloy, and the ABS plastic having dimensions of 96*30*9.9 mm is a USB-like SSD released by ORICO. It is an NVME SSD that has a data transfer speed of 940MB/, and the data consists of 4K videos, high-resolution photos, games, and film. Moreover, it can be connected to the C-C type ports and C- A type data cables and can be connected with the Raspberry Pi without installing any software, just plug and play.

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Conclusion

The SSD drives are more expensive than the HDD drives in respect of the price, but they are of high performance, high durability, and are more reliable than the HDD drives. In this article, the top five best SSD are explored with their prominent specifications, which can be used with the Raspberry Pi.



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Raspberry Pi is an extremely lightweight device utilized to explore computing and learning how to program. However, its processor isn’t that powerful in performing multiple high-computational tasks all at merienda. For example, if you are using this device for mining purposes, it may heat up too early because it doesn’t have much capacity to perform these tasks single handily. In that case, you will surely need to build a Raspberry Pi cluster to speed up the performance of your Raspberry Pi device.

This article will guide you in building your first Raspberry Pi cluster. However, before going into the details, let’s first discuss the Raspberry Pi cluster.

What is Raspberry Pi Cluster

The Raspberry Pi cluster is a series of Raspberry Pi devices connected to share their tasks. A Raspberry Pi cluster includes a central node that takes charge of all the processes and is thus more powerful than other devices.

To find more detail about the Raspberry Pi cluster, you can read our article.

How to build your first Raspberry Pi cluster

To create a Raspberry Pi cluster, you will need the following components:

  • Raspberry Pi 4 devices (4-8 depends on your budget)
  • Raspberry Pi POE HAT devices (One POE for each Raspberry Pi device)
  • Gigabit POE enabled switch (The number of ports in the POE must not be less than the number of Raspberry Pi devices)
  • Ethernet Adaptor to power on the POE enabled switch
  • Cluster Case
  • SSD Drive
  • SD cards (Minimum 32GB) (One for each Raspberry Pi device)
  • Ethernet Cables

After preparing the above components, you are good to start building your first Raspberry Pi cluster using the following steps:

Step 1: Prepare a place for your Raspberry Pi cluster, which must be clean. It’s better to place the Raspberry Pi cluster with a good ventilation system.

Step 2: Now, setup your Raspberry Pi devices by first installing POE HAT as this enables you to power your Raspberry Pi devices through Ethernet enabled networks.

Step 3: After the POE HAT setup, now place each Raspberry Pi device in a cluster carefully one by one.

Step 4: Prepare your Raspberry Pi SD cards and install Raspberry Pi operating system on each card by following the published article guideline.

Step 5: Now insert the SD cards into the Raspberry Pi devices.

Step 6: Power on Raspberry Pi devices.

Step 7: Connect one end of the Ethernet cable with a Raspberry Pi device and the other with the Gigabit POE enabled switch. Power on the switch using an Ethernet adapter. Repeat the same step for all Raspberry Pi devices.

Step 8: Choose a head device that will control all the clustering processes and for that, you have to connect all other devices with it using its Ethernet connection. All other devices will connect to the head device internet connection through the ethernet cable. You can even boost the head device performance by installing an SSD drive.

Step 9: For better performance, you can even install a Fan for each Raspberry Pi device to keep the devices cool.

Step 10: Merienda the setup is completed, use the following command to open the dhcpcd configuring file on your head device where you will require to set static IP for your host.

$ sudo nano /etc/dhcpcd.conf

Uncomment the following lines:

Save the file and reboot your device.

Repeat the same process for all the devices to complete the process of building a Raspberry Pi cluster. In case, if any error occurs, you can get help from the Raspberry Pi tutorial.

Conclusion

Building a Raspberry Pi cluster enhances the performance as multiple Raspberry Pi devices perform their duties simultaneously. The above guidelines will assist you in building your first Raspberry Pi cluster so that you can execute various high computational tasks within no time. You should also carefully select the head node. This performance depends upon the Raspberry Pi devices you buy (Raspberry Pi with 8GB RAM) and storage devices (SSD to boost functionality).



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Stadia is a google cloud gaming service that provides the service to play different high-end AAA games online. You can access Stadia on any device using a web browser. However, on the Raspberry Pi device, you will require to set up a few things so that you would be able to run the platform on the device.

If you don’t know how to run Stadia on Raspberry Pi, go through this article’s guidelines.

How to run Stadia on Raspberry Pi

Running Stadia on Raspberry Pi requires a web browser and some configuration in the device so that it would be able to provide you with a good gaming experience. The following step-by-step instructions will guide you in running the Stadia on Raspberry Pi:

Step 1: Update packages on Raspberry Pi

First, update the Raspberry Pi’s packages using the following command:

To install the upgrade version of packages, using the following command:

Step 2 (Optional): Ensure Chromium Browser is installed

The Raspberry Pi OS already includes Chromium browser, so you can skip this step in case the browser is installed. However, if you accidently deleted the browser, install it through the following command:

$ sudo apt install chromium-browser

Step 3 (Optional): Install Desktop environment

If you are using a light version of Raspberry Pi OS on your device, you will require installing the desktop environment first so that you would be able to use the GUI. The below-given command will assist you in installing the Xfce environment on your device.

$ sudo apt install xserver-xorg xfce4 xfce4-terminal -y

Step 4: Increase the Raspberry Pi Memory

Next, you will need to increase the amount of memory dedicated to your device’s GPU. To do this step, you will need to open the Raspberry Pi configuration first using the following command:

In the configuration, go to the “Performance Options”.

Select “P2 GPU Memory”.

Now, change the number from 64 to 256 if you are using a Raspberry Pi 4 device with 8GB RAM. For 4GB RAM, you can replace the number 64 with 128.

Now, reboot the device for the changes to apply.

After the reboot, open the Chromium-browser on your device and visit the address https://stadia.google.com.

Go to the “Sign in” button.

Sign in with your Gmail Account.

You can also install Stadia onto your Raspberry Pi using by following the below-image guideline.

Click on the “Install” option.

Configuring Stadia on Raspberry Pi

With the Sign in process, you will need to complete the below-mentioned 7 Steps before you will get a chance to use Stadia on Raspberry Pi.

Step 1: In the first step, click on the “Confirm” option to proceed towards the next step.

Step 2: Scroll down and accept the Terms and then click on the “Next” button.

Step 3: Choose your Alteración and then select the “Next” option.

Step 4: Choose a Stadia name by yourself.

Step 5: Click on the “Confirm” option.

Step 6: Choose your privacy settings and then proceed with the “Next” option.

Step 7: If you want to get daily updates, choose the “Sign up for email updates” option or you can proceed with the “Next” button by selecting the “Not now” option.

Step 8: In this step, you will require to purchase the Stadia Pro version so that you can enjoy playing games on it. For that, click on the “Start trial” option and provide your account details.

You can skip the Pro version by choosing the “No Thanks” option.

This shows the Stadia dash board on the browser.

Now, that Stadia is running on your Raspberry Pi, look for the free games.

Click on any game to run it on your browser.

You can purchase many AAA games and enjoy a seamless gaming experience right into your browser tab.

Conclusion

Stadia is a perfect online gaming platform designed especially for game lovers to enjoy a seamless gaming experience on their web browsers. After performing the steps mentioned above, it can easily run on your Raspberry Pi device. You can play some free games and purchase the Stadia Pro subscription to play high-end games.



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Raspberry Pi device is a portable mini-computer where you can easily install an operating system. It includes a robust processor with a large memory storage that can go up to 8GB thus keeps your system performance well up to the mark. However, most people are unaware about running multiple operating systems on Raspberry Pi devices. This article is written to help you in running multiple operating systems on your Raspberry Pi using the dual boot process.

Dual boot on Raspberry Pi – Step-by-Step Guide

There are different ways to use dual boot on Raspberry Pi but here we will show you the easiest one to follow which requires simple steps given below:

Step 1: First, visit the website on your system browser.

Step 2: Select your Raspberry Pi storage option.

Step 3: Next, select your Raspberry Pi model.

Step 4: There you will find different operating systems ranging from light versions to full ones. Pick any two operating systems according to your choice. In our case, we picked DietPi and Raspberry Pi OS Lite (32-bit).

Step 5: Set your partition size for each operating system or go with the default option.

Step 6: Now, download both files “pinn-lite” and “recovery-cmdline” on your system.

Step 7: Now, insert the SD card into your system format using the FAT32 system as this operation will only work on the FAT32 system.

Step 8: Next, extract the content of “pinn-lite” to FAT32 formatted SD card as well as copy the “recovery-cmdline” file into the SD card as this will replace the previous cmdline file in the directory.

Step 9: Now, remove the card, power on your device and insert the card into the device SD-card port. After few seconds, you will see the dual boot setup process as shown below:

Step 10: Connect to your WIFI network using the “Wifi” option.

Step 11: Proceed toward the “Install” option after selecting both the operating system that appears on your screen.

This begins the dual boot process on your Raspberry Pi device.

This may take a longer time depending on your Wifi speed but when the process completes, you will be able to use two operating systems on your Raspberry Pi. You have to choose the operating system order according to your choice.

Whenever you turn on your device, you will see the above screen. You have to place the OS on top which you want to use and then click on the “BOOT” button to enter the selected system.

Conclusion

The dual boot process allows Raspberry Pi users to use multiple operating systems on their devices. It is beneficial for those who don’t want to rely on a single operating system as this will help them change their operating system any time depending on their needs. The above steps will provide you with the simple way to install two operating systems through an online platform that won’t require any third-party tool. You just need to copy the contents to your SD card and the process will prepare the dual boot setup on your Raspberry Pi device.



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The Raspberry Pi uses the SD-card as a primary storage device allowing users the space to install different applications or packages on the device. However, it also gets hammered with the presence of excess log files (system record files) that may reduce the performance and lifespan of the SD-card. Log2RAM is a bunch of scripts designed especially for the Raspberry Pi users that changes the physical location of log files to RAM in order to increase the SD card performance.

In this tutorial, you will see how you can improve the SD card performance of Raspberry Pi using Log2RAM.

Improve SD card performance of Raspberry Pi using Log2RAM

Log2RAM pushes the log files to the RAM and these files get deleted upon reboot because RAM is a volatile memory. The following steps will guide you in improving your Raspberry Pi’s SD card performance through Log2RAM:

Step 1: Update Raspberry Pi

First, run the following commands to update the packages on your Raspberry device.

$ sudo apt update && sudo apt upgrade

Step 2: Install Rsync

Next, you will need to install Rsync software on your Raspberry Pi device that allows you to synchronize the contents between the two parties (source and destination).

Step 3: Add GPG Key

Now, add GPG key require to successfully add Log2RAM repository using the following command:

$ sudo wget -O /usr/share/keyrings/azlux-archive-keyring.gpg  https://azlux.fr/repo.gpg

Step 4: Add Log2RAM Repository

Next, you will require to add a Log2RAM repository using the following command in order to install the latest version of the software on your Raspberry Pi.

$ echo «deb [signed-by=/usr/share/keyrings/azlux-archive-keyring.gpg] http://packages.azlux.fr/debian/ bullseye main» | sudo tee /etc/apt/sources.list.d/azlux.list

Step 5: Update Packages

After adding the Log2RAM repository, update Raspberry Pi packages list through following command:

The above output confirms that the repository list is successfully updated on Raspberry Pi.

Step 6: Install Log2RAM

Now, you can install Log2RAM on Raspberry Pi through following command:

$ sudo apt install log2ram

Step 7: Reboot Raspberry Pi

After the installation, reboot the Raspberry Pi device.

Step 8: Check Log2RAM Status

After the reboot, check Log2RAM status using the following command:

$ systemctl status log2ram.service

Step 9: Configuring Log2RAM

After the reboot, use the following command to open configuration file of Log2RAM on Raspberry Pi:

$ sudo nano /etc/log2ram.conf

Now, you will need to specify the amount of RAM you want to allocate for the mount by locating the line “SIZE=40M”. You can set the size to a maximum 128M. You can proceed to the next step as 40M is enough for the log files as they aren’t large enough to fill up the space.

After ensuring and configuring the Log2RAM service on your Raspberry Pi, your log files will now synchronize to SD card and it will also limit the amount of data on your SD card. Thus, it helps to extend your SD card lifespan. To view the log files go to the location”/varhdd.log”.

You can also confirm the Log2RAM allocation using the following command:

The above output confirms that Log2RAM is successfully configured on Raspberry Pi and all your Raspberry Pi records are stored in it.

Conclusion

Log2RAM offload the record files to RAM on your Raspberry Pi, thus reducing the number of writes to the SD card. With this tool, the lifespan of the Raspberry Pi SD card is greatly improved. The above-mentioned steps will help you in increasing your SD card performance by installing Log2RAM. After the installation and configuration, it will handle the log files by itself.



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Grafana is a multi-platform open-source visualization tool with an online web-based interface allowing users to maestro their system metrics on their Raspberry Pi device. It has a built-in alert manager that keeps you updated whenever the server receives data. It also includes visualization options like charts and graphs which are generated from data source and you can view them directly onto your browser tab. With the inclusion of different built-in plugins, you can also use Grafana service on a cloud environment.

This article provides a detailed guideline to install Grafana on Raspberry Pi.

Install Grafana on Raspberry Pi

The installation of Grafana on Raspberry Pi is super easy as it doesn’t require any additional dependencies to operate on your device. Follow the below-given steps to install Grafana on your device.

Step 1: Update Packages

First, you are advised to update packages on your Raspberry Pi device through the following command:

$ sudo apt update && sudo apt upgrade -y

Step 2: Adding GPG Key on Raspberry Pi

Next, add the GPG key through below-mentioned command:

$ curl https://packages.grafana.com/gpg.key | gpg –dearmor | sudo tee /usr/share/keyrings/grafana-archive-keyrings.gpg >/dev/null

Step 3: Adding Grafana Repository

After adding the key, use the following command to add Grafana repository to the Raspberry Pi list.

$ echo «deb [signed-by=/usr/share/keyrings/grafana-archive-keyrings.gpg] https://packages.grafana.com/oss/deb stable main» | sudo tee /etc/apt/sources.list.d/grafana.list

Step 4: Update Repository

After adding the Grafana repository, execute the below-given command to update Raspberry Pi packages list.

Step 5: Installing Grafana on Raspberry Pi

Merienda the repository is added, you are now set to install Grafana on Raspberry Pi through following command:

$ sudo apt install grafana

Step 6: Enable Grafana Service

After completing the above steps, enable Grafana service on your Raspberry Pi through the following command:

$ sudo systemctl enable grafana-server

Step 7: Start Grafana Service

Then use the following command to start Grafana service on your Raspberry Pi device:

$ sudo systemctl start grafana-server

You can check the status through following command:

$ sudo systemctl status grafana-server

Step 8: Running Grafana

Now that Grafana service is running fine on Raspberry Pi, you are good to access its dashboard on your browser tab. However, before that, you will need to find the Raspberry Pi host address through following command:

Then use the address https://192.168.18.218:3000 in your browser to open the Grafana GUI interface.

Type “admin” as your default email/username and password. Then choose the“Log in” option.

As the default password is insecure, you will need to change it in the next step.

As soon as you click on the “Submit” button, you will be able to see the Grafana dashboard on your browser.

This completes the Grafana installation on your Raspberry Pi device. In case you need assistance, go to the Grafana documentation to acquire the basic understanding of using this tool.

Conclusion

Grafana is a robust web-based application designed specially to visualize time-series data. It includes an online dashboard where you can see different options to view your Raspberry Pi board’s performance. It can easily be installed on Raspberry Pi using the source key and repository that needs to be added to the system packages list. Afterwards, you can access its dashboard on your browser’s tab through the device IP address.



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Raspberry Pi OS is an ARM based operating system that won’t allow you to directly run Windows applications on its environment. However, with the inclusion of Box64, the users will be able to run x64 applications with ease. Box64 is an emulation platform that converts the x64 program instructions to ARM instructions, allowing users to easily run x64 applications on Raspberry Pi desktop.

This tutorial guides you in installing Box64 on Raspberry Pi.

How to install Box64 on Raspberry Pi

In order to install Box64 on your Raspberry Pi operating system, you will first need to ensure that your OS must be 64-Bit version. To check the version of Raspberry Pi, use the following command:

The above output “aarch64” confirms the presence of the 64-Bit version. Now, you will require to perform following steps to run x64 applications on Raspberry Pi using Box64:

Step 1: Update Packages

First, check the Raspberry Pi packages update using the following command:

If packages are not updated, use the following command to upgrade them:

Step 2: Build essential packages

After the update, use the following command to install some packages required to run Box64 on Raspberry Pi.

$ sudo apt install git build-essential cmake

Step 3: Clone Box64 repository

Merienda the above installation is successful, you can then execute the following command to clone Box64 repository from git.

$ git clone https://github.com/ptitSeb/box64.git

Step 4: Compile Box64

After completing the cloning process, it’s now time to run the Box64 on Raspberry Pi using the following steps:

1: Navigate to Box64 directory by issuing the following command:

2: Now, create a directory with the name “build” using the following command so that the Box64 compilation files will be put into this folder.

3: Go to the “build” directory using the following command:

4: Now, generate some configuration files which helps to efficiently compile Box64 on Raspberry Pi.

$ cmake .. -DRPI4ARM64=1 -DCMAKE_BUILD_TYPE=RelWithDebInfo

5: After successfully generating the above files, execute the following command to compile Box64:

6: After completing the installation process, execute the following command to install Box64 on Raspberry Pi.

7: In the end, use the following command to restart binfmt service as this will help Raspberry Pi understand that it can run x64 applications using Box64.

$ sudo systemctl restart systemd-binfmt

After completing the above steps, reboot the device for the changes to take place. To confirm the Box64 version, use the following command:

The above output confirms that the latest version of Box64 is installed on Raspberry Pi.

Conclusion

Box64 is a perfect emulation platform that allows the users to run x64 applications on the 64-Bit Raspberry Pi operating system. The installation of Box64 is pretty simple which can be completed after cloning its repository into the Raspberry Pi repository list. Afterwards, you can use the make and build commands to install the required files for running the Box64 application on Raspberry Pi desktop.



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Want to run Windows application on your Raspberry Pi desktop? Try out Wine. It’s a multi-format reader designed specially to run Windows applications on different platforms such as Linux, Debian, Fedora and so on. It’s a lightweight compatibility layer that efficiently runs on your Raspberry Pi desktop without reducing the device performance.

This guide will show you how you can install Wine on your Raspberry Pi device and install Windows applications with ease.

How to run Windows Applications on Raspberry Pi using Wine

Installing Wine on Raspberry Pi is pretty simple, thanks to the Raspberry Pi developers, which includes the repository of Wine, making it easier for you to install the application. The below-given steps will guide you in installing Wine in on Raspberry Pi:

Step 1: Update Raspberry Pi Packages

Before installing any application, ensure that your packages are updated. To confirm it, execute the following command:

$ sudo apt update && sudo apt upgrade

Step 2: Adding i386 Architecture

Wine works on i386 architecture and if you are using other architecture you will need to change it using the following command:

$ sudo dpkg –add-architecture i386

Step 2: Install Wine

After completing the above steps, you can install Wine on Raspberry Pi using the following command:

Enter “Y” to begin the Wine installation on your Raspberry Pi device.

After completing the installation, open Wine configuration on your Raspberry Pi device using the following command:

The above command will open the Wine configuration. You can select your Windows version according to your choice.

Installing Windows Application on Raspberry Pi

Now, to install an application on Raspberry Pi, you will first need to download a Windows application in “.exe” format.

In our case, we are going to download the VLC media player as an example for you to learn how you can install Windows applications. After the download, look for the location where your file is downloaded. It may differ in your case, but mostly, it’s located in the “Downloads” directory.

To install the application, first visit the location in the terminal using the following command:

Then use the following command to run the application using Wine.

$ wine <application_name>

Complete the remaining installation steps to install VLC media player on your Raspberry Pi OS. Then issue the following command to run the VLC media player on Raspberry Pi.

In this way, you can install multiple Windows applications with ease.

Conclusion

Wine is a perfect solution that allows Raspberry Pi users to install and run Windows applications easily. The installation of Wine on Raspberry Pi is quiebro simple, as mentioned in the above guidelines, it requires only an i386 architecture and an installation command. After installing, you can download any Windows application and run it on the terminal using the “wine” command with the application name.



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Jellyfin is a free and open-source online media solution designed to manage, organize and share media files to other networked devices. It lets you run your media files directly onto your browser via its web dashboard. You can install it on any platform, such as Windows, Linux and macOS.

If you want to install Jellyfin on Raspberry Pi, you should follow the guidelines provided in the article so that you will be able to access the Jellyfin web interface.

Installing Jellyfin on Raspberry Pi

The Raspberry Pi OS doesn’t include the Jellyfin repository; thus, you cannot install it directly onto your system. After adding the repository, you can then install it on your device. The following simple steps-by-step instructions will help you in installing Jellyfin on your Raspberry Pi device:

Step 1: Update Packages list of Raspberry Pi

Initially, you will need to update your packages list installed on your Raspberry Pi through following command:

$ sudo apt update && sudo apt upgrade

Step 2: Add GPG Key

Now add GPG key using the following command to verify the package authenticity:

$ sudo wget -O- https://repo.jellyfin.org/jellyfin_team.gpg.key | gpg –dearmor | sudo tee /usr/share/keyrings/jellyfin.gpg

Step 3: Add Jellyfin Repository

By updating the packages on Raspberry Pi, it’s now time to add Jellyfin repository in Raspberry Pi repository list through following command:

$ echo «deb [arch=$( dpkg –print-architecture ) signed-by=/usr/share/keyrings/jellyfin.gpg] https://repo.jellyfin.org/debian bullseye main» | sudo tee /etc/apt/sources.list.d/jellyfin.list

Step 4: Update Raspberry Pi Repository List

After adding the Jellyfin repository, use the following command to update the Raspberry Pi repository list.

Step 5: Install Jellyfin

After the update, you can install the Jellyfin on your Raspberry Pi device through following command:

$ sudo apt install jellyfin

Check Jellyfin version through following command:

The above output shows that the latest version of Jellyfin is installed on your system.

You can check the Jellyfin running status using the following command:

$ systemctl status jellyfin

To enable Jellyfin after the system reboots, use the following command:

$ sudo systemctl enable jellyfin

Step 6: Access the Jellyfin Web Interface

Now, to access the Jellyfin web interface on your browser, first you will need to find out your Raspberry Pi IP address using the following command:

Then use the address “http://192.168.18.218:8096” on your browser to open the web interface of Jellyfin. In the address, change the IP address with your device IP address.

This will open the Jellyfin welcome page on your browser. Proceed towards the next step using the “Next” option.

Set your Jellyfin account username and password.

You can click on the “Add Library” to add your media files from here or simply choose the “Next” button to add the files later.

Choose your language,

Allow remote connections and proceed to the next step.

Click on the “Finish” option to view Jellyfin dashboard.

Sign in with your Jellyfin account.

This shows the Jellyfin dashboard on your browser.

Now, you can add media libraries such as photos, videos and any other file and can run it on your browser because the Jellyfin server is now successfully loaded up on your browser.

This completes the Jellyfin setup.

Conclusion

Jellyfin is an open-source online application that allows access to the media from an online server. On Raspberry Pi, you can install it by adding the source repository and using the apt installer. You can then access Jellyfin dashboard on any web browser using the Raspberry Pi IP address and with proper configuration, you will then be able to use its web interface.



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