fidzu : mobile

Posted by Andrew Lewis, Software Engineer

Media3 1.10 is out!
Media3 1.10 includes new features, bug fixes and feature improvements, including Material3-based playback widgets, expanded format support in ExoPlayer and improved speed adjustment when exporting media with Transformer. Read on to find out more, and check out the full release notes for a comprehensive list of changes.

Playback UI and Compose

We are continuing to expand the media3-ui-compose-material3 module to help you build Compose UIs for playback.

We've added a new Player Composable that combines a ContentFrame with customizable playback controls, giving you an out-of-the-box player widget with a modern UI.

This release also adds a ProgressSlider Composable for displaying player progress and performing seeks using dragging and tapping gestures. For playback speed management, a new PlaybackSpeedControl is available in the base media3-ui-compose module, alongside a styled PlaybackSpeedToggleButton in the Material 3 module.

We'll continue working on new additions like track selection utils, subtitle support and more customization options in the upcoming Media3 releases. We're eager to hear your feedback so please share your thoughts on the project issue tracker.

Player Composable in the Media3 Compose demo app

30 Mar 2026 11:00pm GMT

Posted by Ben Weiss, Senior Developer Relations Engineer

Monzo is a UK digital bank with 15 million customers and growing. As the app scaled, the engineering team identified app startup time as a critical area for improvement but worried it would require significant changes to their codebase.

By fully enabling R8 optimizations, Monzo achieved a massive 35% reduction in their Application Not Responding (ANR) rate. This simple change proved that impactful optimizations don't always require complex engineering efforts.

Unlocking broad performance wins with R8 full mode

Monzo identified R8 full mode as an easy fix worth trying; and it worked, improving performance across the board:

• ● Startup Reliability: Cold starts improved by 30%, Warm starts by 24%, and Hot starts by 14%.
• ● Launch Speed: P50 launch times improved by 11% and P90 launch times by 12%.
• ● Efficiency: Overall app size was reduced by 9%.
• ● Stability: ANR reduction of 35%.

Enabling optimizations with a single change

Many Android apps use an outdated default configuration file which disables most functionality of the R8 optimizer. The main change Monzo made to unlock these performance improvements was to replace the proguard-android.txt default file with proguard-android-optimize.txt. This change removes the -dontoptimize instruction and allows R8 to properly do its job.

buildTypes {
  release {
    isMinifyEnabled = true
    isShrinkResources = true
    proguardFiles(
      getDefaultProguardFile("proguard-android-optimize.txt"),
    )
  }
}

After making this change, it's worth looking at your Keep configuration files. These files tell R8 which parts of your code to leave alone (usually because they're called dynamically or by external libraries). Tidying up unnecessary Keep rules means R8 can do more.

Improving scroll performance with Baseline Profiles

To further enhance the user experience, Monzo implemented Baseline Profiles, specifically targeting scroll and rendering performance on their main feed. This strategy ensured that the most common user journeys-opening the app and scrolling the feed-were fully optimized. The impact on rendering was substantial: P90 scroll performance became 71% faster, and P95 scroll performance improved by 87%. Now scrolling the app is smoother than before.

Monzo built this into their release process to maintain these improvements over time. "We trigger the baseline profile generation every week day (before running our nightly builds) and commit the latest changes once completed," Neumayer explains.

Keeping up with modern Android development

Monzo's experience shows what's possible when you stay up to date with Android build-tooling recommendations. While legacy apps often struggle with complex reflection usage, Monzo found the transition straightforward by documenting their Keep Rules properly. "We always add a comment explaining why Keep Rules are in place, so we know when it's safe to remove the rules," Neumayer notes.

Neumayer's advice for other teams? Regularly check your practices against current standards: "Take a look at the latest recommendations from Google around app performance and check if you're following all the latest advice."

To get started and learn more about R8, visit https://d.android.com/r8

30 Mar 2026 10:00pm GMT

Android is for everyone. It's built on a commitment to an open and safe platform. Users should feel confident installing apps, no matter where they get them from. However, our recent analysis found over 90 times more malware from sideloaded sources than on Google Play. So as an extra layer of security, we are rolling out Android developer verification to help prevent malicious actors from hiding behind anonymity to repeatedly spread harm. Over the past several months, we've worked closely with the community to improve the design so we account for the many ways people use Android to balance openness with safety.

Start your verification today

Today, we're starting to roll out Android developer verification to all developers in both the new Android Developer Console and Play Console. This allows you to complete your verification and register your apps before user-facing changes begin later this year.

• If you only distribute apps outside of Google Play, you can create an account in Android Developer Console today.
• If you're on Google Play, check your Play Console account for updates over the next few weeks. If you've already verified your identity here, then you're likely already set.

Most of your users' download experience will not change at all

While verification tools are rolling out now, the experience for users downloading your apps will not change until later this year. The user side protections will first go live in Brazil, Indonesia, Singapore, and Thailand this September, before expanding globally in 2027. We've shared this timeline early to ensure you have ample time to complete your verification.

Following this deadline, for the vast majority of users, the experience of installing apps will stay exactly the same. It's only when a user tries to install an unregistered app that they'll require ADB or advanced flow, helping us keep the broader community safe while preserving the flexibility for our power users.

Developers can still choose where to distribute their apps. Most users' download experience will not change

Tailoring the verification experience to your feedback

To balance the need for safety with our commitment to openness, we've improved the verification experience based on your feedback. We've streamlined the developer experience to be more integrated with existing workflows and maintained choice for power users.

• For Android Studio developers: In the next two months, you'll see your app's registration status right in Android Studio when you generate a signed App Bundle or APK.

You'll see your app's registration status in Android Studio when you generate a signed App Bundle or APK.

• For Play developers: If you've completed Play Console's developer verification requirements, your identity is already verified and we'll automatically register eligible Play apps for you. In the rare case that we are unable to register your apps for you, you will need to follow the manual app claim process. Over the next couple of weeks, more details will be provided in the Play Console and through email. Also, you'll be able to register apps you distribute outside of Play in the Play Console too.

The Android developer verification page in your Play Console will show the registration status for each of your apps.

• For students and hobbyists: To keep Android accessible to everyone, we're building a free, no government ID required, limited distribution account so you can share your work with up to 20 devices. You only need an email account to get started. Sign up for early access. We'll send invites in June.
• For power users: We are maintaining the choice to install apps from any source. You can use the new advanced flow for sideloading unregistered apps or continue using ADB. This maintains choice while protecting vulnerable users.

What's next?

We're rolling this out carefully and working closely with developers, users, and our partners. In April, we'll introduce Android Developer Verifier, a new Google system service that will be used to check if an app is registered to a verified developer.

• April 2026: Users will start to see Android Developer Verifier in their Google Systems services settings.
• June 2026: Early access: Limited distribution accounts for students and hobbyists.
• August 2026:
• • Limited distribution accounts launch globally.
  • Advanced flow for power users launches globally.
• September 30, 2026: Apps must be registered by verified developers in order to be installed and updated on certified Android devices in Brazil, Indonesia, Singapore, and Thailand. Unregistered apps can be sideloaded with ADB or advanced flow.
• 2027 and beyond: We will roll out this requirement globally.

We're committed to an Android that is both open and safe. Check out our developer guides to get started today.

30 Mar 2026 8:00pm GMT

Here to save you time and effort

30 Mar 2026 7:27pm GMT

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30 Mar 2026 3:30pm GMT

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30 Mar 2026 3:00pm GMT

I've mentioned some of my various retronetworking projects in some past blog posts. One of those projects is Osmocom Community TDM over IP (OCTOI). During the past 5 or so months, we have been using a number of GPS-synchronized open source icE1usb interconnected by a new, efficient but strill transparent TDMoIP protocol in order to run a distributed TDM/PDH network. This network is currently only used to provide ISDN services to retronetworking enthusiasts, but other uses like frame relay have also been validated.

So far, the central hub of this OCTOI network has been operating in the basement of my home, behind a consumer-grade DOCSIS cable modem connection. Given that TDMoIP is relatively sensitive to packet loss, this has been sub-optimal.

Luckily some of my old friends at noris.net have agreed to host a new OCTOI hub free of charge in one of their ultra-reliable co-location data centres. I'm already hosting some other machines there for 20+ years, and noris.net is a good fit given that they were - in their early days as an ISP - the driving force in the early 90s behind one of the Linux kernel ISDN stracks called u-isdn. So after many decades, ISDN returns to them in a very different way.

Side note: In case you're curious, a reconstructed partial release history of the u-isdn code can be found on gitea.osmocom.org

But I digress. So today, there was the installation of this new OCTOI hub setup. It has been prepared for several weeks in advance, and the hub contains two circuit boards designed entirely only for this use case. The most difficult challenge was the fact that this data centre has no existing GPS RF distribution, and the roof is ~ 100m of CAT5 cable (no fiber!) away from the roof. So we faced the challenge of passing the 1PPS (1 pulse per second) signal reliably through several steps of lightning/over-voltage protection into the icE1usb whose internal GPS-DO serves as a grandmaster clock for the TDM network.

The equipment deployed in this installation currently contains:

• a rather beefy Supermicro 2U server with EPYC 7113P CPU and 4x PCIe, two of which are populated with Digium TE820 cards resulting in a total of 16 E1 ports

• an icE1usb with RS422 interface board connected via 100m RS422 to an Ericsson GPS03 receiver. There's two layers of of over-voltage protection on the RS422 (each with gas discharge tubes and TVS) and two stages of over-voltage protection in the coaxial cable between antenna and GPS receiver.

• a Livingston Portmaster3 RAS server

• a Cisco AS5400 RAS server

For more details, see this wiki page and this ticket

Now that the physical deployment has been made, the next steps will be to migrate all the TDMoIP links from the existing user base over to the new hub. We hope the reliability and performance will be much better than behind DOCSIS.

In any case, this new setup for sure has a lot of capacity to connect many more more users to this network. At this point we can still only offer E1 PRI interfaces. I expect that at some point during the coming winter the project for remote TDMoIP BRI (S/T, S0-Bus) connectivity will become available.

18 Sep 2022 10:00pm GMT

Almost one year after my post regarding first steps towards a V5 implementation, some friends and I were finally able to visit Wobcom, a small German city carrier and pick up a lot of decommissioned POTS/ISDN/PDH/SDH equipment, primarily V5 access networks.

This means that a number of retronetworking enthusiasts now have a chance to play with Siemens Fastlink, Nokia EKSOS and DeTeWe ALIAN access networks/multiplexers.

My primary interest is in Nokia EKSOS, which looks like an rather easy, low-complexity target. As one of the first steps, I took PCB photographs of the various modules/cards in the shelf, take note of the main chip designations and started to search for the related data sheets.

The results can be found in the Osmocom retronetworking wiki, with https://osmocom.org/projects/retronetworking/wiki/Nokia_EKSOS being the main entry page, and sub-pages about

• Node Control Unit

• 16x BRI Uk0 Line Card

• 32x POTS Line Card

• Line Measurement Unit

• Shelf

In short: Unsurprisingly, a lot of Infineon analog and digital ICs for the POTS and ISDN ports, as well as a number of Motorola M68k based QUICC32 microprocessors and several unknown ASICs.

So with V5 hardware at my disposal, I've slowly re-started my efforts to implement the LE (local exchange) side of the V5 protocol stack, with the goal of eventually being able to interface those V5 AN with the Osmocom Community TDM over IP network. Once that is in place, we should also be able to offer real ISDN Uk0 (BRI) and POTS lines at retrocomputing events or hacker camps in the coming years.

08 Sep 2022 10:00pm GMT

If you have ever worked with Digium (now part of Sangoma) digital telephony interface cards such as the TE110/410/420/820 (single to octal E1/T1/J1 PRI cards), you will probably have seen that they always have a timing connector, where the timing information can be passed from one card to another.

In PDH/ISDN (or even SDH) networks, it is very important to have a synchronized clock across the network. If the clocks are drifting, there will be underruns or overruns, with associated phase jumps that are particularly dangerous when analog modem calls are transported.

In traditional ISDN use cases, the clock is always provided by the network operator, and any customer/user side equipment is expected to synchronize to that clock.

So this Digium timing cable is needed in applications where you have more PRI lines than possible with one card, but only a subset of your lines (spans) are connected to the public operator. The timing cable should make sure that the clock received on one port from the public operator should be used as transmit bit-clock on all of the other ports, no matter on which card.

Unfortunately this decades-old Digium timing cable approach seems to suffer from some problems.

08 Sep 2022 10:00pm GMT