On this page:
15.1 Objectives
15.2 Prerequisites
15.3 Logging In
15.4 Creating a simple srs  LTE experiment
15.5 Exploring Your Experiment
15.5.1 Experiment Status
15.5.2 Profile Instructions
15.5.3 Topology View
15.5.4 List View
15.5.5 Manifest View
15.5.6 Graphs View
15.5.7 Actions
15.5.8 Web-based Shell
15.6 Using the srs  LTE tools
15.7 Digging deeper
15.8 Terminating the Experiment
15.9 Taking Next Steps
2020-07-23 (06836dc)

15 Powder basic srsLTE Tutorial

This tutorial will walk you through the process of creating a single node experiment running srsLTE software for simulated UE/eNodeB interaction (i.e., without SDR hardware). Your experiment will run on a bare-metal machine that is dedicated for your use for the duration of your experiment. You will have complete administrative access to this machines, meaning that you have full ability to customize and modify the srsLTE code, or install other software as needed.

15.1 Objectives

In the process of taking this tutorial, you will learn to:

15.2 Prerequisites

This tutorial assumes that you have an existing account on Powder (Instructions for getting an account can be found here.)

15.3 Logging In

The first step is to log in to Powder; Powder is available to researchers and educators who work in radio networking and have accepted the Powder AUP. If you have an account at one of its federated facilities, like Emulab or CloudLab, then you already have an account at Powder. screenshots/powder/powder-front-page.png

15.4 Creating a simple srsLTE experiment

Once you have logged in to Powder, you will “instantiate” a “profile” to create an experiment. Profiles are Powder’s way of packaging up configurations and experiments so that they can be shared with others. Each experiment is separate: the experiment that you create for this tutorial will be an instance of a profile provided by the facility, but running on resources that are dedicated to you, which you have complete control over. This profile uses local disk space on the nodes, so anything you store there will be lost when the experiment terminates.

The experiment you will instantiate in this tutorial is very small, but Powder will have city-scale infrastructure that can be used for larger-scale experiments.

For this tutorial, we will use a basic profile that brings up a single compute node with srsLTE software pre-installed. As such there is no actual RF involved, rather, tools provided by srsLTE will be used to perform "emulated" interaction between a UE and eNodeB. The Powder staff have built this profile by capturing disk images of an srsLTE install and making it available in a single node profile. See this manual’s section on profiles for more information about how profiles work.

  1. Start Experiment
    screenshots/powder/powder-start-experiment-menu.png
    After logging in, you are taken to your main status dashboard. Select “Start Experiment” from the “Experiments” menu.

  2. Select a profile
    screenshots/powder/powder-srs-2.png
    The “Start an Experiment” page is where you will select a profile to instantiate. For this tutorial we will use the srsLTE-SIM profile, which is the default profile on Powder, so you should be able to simply select "Next" to proceed.
    If it is not the default you may find the srsLTE-SIM profile as follows: Follow this link or click the “Change Profile” button, enter “srsLTE-SIM” in the search box, select “srsLTE-SIM” from the list on the left and click “Select Profile”.
    screenshots/powder/powder-srs-1.png
    Once you have the correct profile selected, click “Next”
    screenshots/powder/powder-srs-2.png

  3. Finalize
    screenshots/powder/powder-srs-3.png
    More complex profiles will have a “Parameterize” step. For the profile used in this tutorial we jump directly to the “Finalize” step.
    Here you can optionally provide a name for your experiment. If you don’t, Powder will make a name for you.
    In the “Finalize” step you need to select a “Cluster”. For this profile, select “Emulab” from the dropdown menu.
    Click “Next” to proceed.

  4. Schedule
    screenshots/powder/powder-srs-4.png
    In the “Schedule” step, go with the default ”Start immediately” and select “Finish”. Powder will start provisioning the resources you requested.

  5. Powder instantiates your profile
    Powder will take a few minutes to bring up your experiment, as many things happen at this stage, including selecting suitable hardware, loading disk images on local storage, booting bare-metal machines, re-configuring the network topology, etc. While this is happening, you will see this status page:
    screenshots/powder/powder-srs-5.png

    Provisioning is done using the GENI APIs; it is possible for advanced users to bypass the Powder portal and call these provisioning APIs from their own code. A good way to do this is to use the geni-lib library for Python.

    As soon as a set of resources have been assigned to you, you will see details about them at the bottom of the page (though you will not be able to log in until they have gone through the process of imaging and booting.)

  6. Your experiment is ready!
    screenshots/powder/powder-srs-6.png
    When the web interface reports the state as “Ready”, your experiment is provisioned, and you can proceed to the next section.

15.5 Exploring Your Experiment

Now that your experiment is ready, take a few minutes to look at various parts of the Powder status page to help you understand what resources you’ve got and what you can do with them.

15.5.1 Experiment Status

The panel at the top of the page shows the status of your experiment—you can see which profile it was launched with, when it will expire, etc. The buttons in this area let you make a copy of the profile (so that you can customize it), ask to hold on to the resources for longer, or release them immediately.

screenshots/powder/powder-srs-6.png

Note that the default lifetime for experiments on Powder is less than a day; after this time, the resources will be reclaimed and their disk contents will be lost. If you need to use them for longer, you can use the “Extend” button and provide a description of why they are needed. Longer extensions require higher levels of approval from Powder staff. You might also consider creating a profile of your own if you might need to run a customized environment multiple times or want to share it with others.

You can click the title of the panel to expand or collapse it.

15.5.2 Profile Instructions

Profiles may contain written instructions for their use. Clicking on the title of the “Profile Instructions” panel will expand (or collapse) it; in this case, the instructions provide details on how to run the pre-installed srsLTE eNodeB and UE tools

screenshots/powder/powder-srs-7.png

15.5.3 Topology View

At the bottom of the page, you can see the topology of your experiment. This profile has a single compute node. The names given for nodes in an experiment are the names assigned as part of the profile; this way, every time you instantiate a profile, you can refer to the nodes using the same names, regardless of which physical hardware was assigned to them. The green boxes around each node indicate that they are up; click the “Refresh Status” button to initiate a fresh check.

screenshots/powder/powder-srs-8.png

It is important to note that most nodes in Powder have at least two network interfaces: one “control network” that carries public IP connectivity, and one “experiment network” that is isolated from the Internet and all other experiments. It is the experiment net that is shown in this topology view. You will use the control network to ssh into your nodes and interact with them. This separation gives you more freedom and control in the private experiment network, and sets up a clean environment for repeatable research.

15.5.4 List View

The list view tab shows similar information to the topology view, but in a different format. It shows the identities of the nodes you have been assigned, and the full ssh command lines to connect to them. In some browsers (those that support the ssh:// URL scheme), you can click on the SSH commands to automatically open a new session. On others, you may need to cut and paste this command into a terminal window. Note that only public-key authentication is supported, and you must have set up an ssh keypair on your account before starting the experiment in order for authentication to work.

screenshots/powder/powder-srs-9.png

15.5.5 Manifest View

The third default tab shows a manifest detailing the hardware that has been assigned to you. This is the “request” RSpec that is used to define the profile, annotated with details of the hardware that was chosen to instantiate your request. This information is available on the nodes themselves using the geni-get command, enabling you to do rich scripting that is fully aware of both the requested topology and assigned resources.

Most of the information displayed on the Powder status page comes directly from this manifest; it is parsed and laid out in-browser.

screenshots/powder/powder-srs-10.png

15.5.6 Graphs View

The final default tab shows a page of CPU load and network traffic graphs for the nodes in your experiment. On a freshly-created experiment, it may take several minutes for the first data to appear. After clicking on the “Graphs” tab the first time, a small reload icon will appear on the tab, which you can click to refresh the data and regenerate the graphs.

screenshots/powder/powder-srs-11.png

15.5.7 Actions

In both the topology and list views, you have access to several actions that you may take on individual nodes. In the topology view, click on the node to access this menu; in the list view, it is accessed through the icon in the “Actions” column. Available actions include rebooting (power cycling) a node, and re-loading it with a fresh copy of its disk image (destroying all data on the node). While nodes are in the process of rebooting or re-imaging, they will turn yellow in the topology view. When they have completed, they will become green again. The shell action is described in more detail below.

screenshots/powder/powder-srs-12.png

15.5.8 Web-based Shell

Powder provides a browser-based shell for logging into your nodes, which is accessed through the action menu described above. While this shell is functional, it is most suited to light, quick tasks; if you are going to do serious work, on your nodes, we recommend using a standard terminal and ssh program.

This shell can be used even if you did not establish an ssh keypair with your account.

Two things of note:

screenshots/powder/powder-srs-13.png

15.6 Using the srsLTE tools

srsLTE provide software which, when paired with SDR hardware, can realize fully functional UE and eNodeB functionality. In this profile we will use more basic srsLTE provided tools to “emulate” UE and eNodeB interaction.

To "send" traffic from the eNodeB to an output file:

/usr/local/srsLTE/build/lib/examples/pdsch_enodeb -o foo -n 5 -m 9 -v

screenshots/powder/powder-srs-14.png

To "receive" traffic at the UE from the output file:

/usr/local/srsLTE/build/lib/examples/pdsch_ue -i foo -n 5 -r 1234 -v -d

screenshots/powder/powder-srs-15.png

You should see output related to the “emulated” eNodeB/UE interaction.

The node has both the srsGUI library (for real time display) and the srsLTE source code installed. (See below.)

If you have ssh and X working on your setup, you should be able to run the receive command without the -d option to get a “real time” display of the signals “received” the UE. You would need to increase the number sub-frames generated. E.g.:

/usr/local/srsLTE/build/lib/examples/pdsch_enodeb -o foo -n 10000 -m 9 -v

/usr/local/srsLTE/build/lib/examples/pdsch_ue -i foo -n 10000 -r 1234 -v

15.7 Digging deeper

Relevant pointers to dig deeper:

For real time plots compile and install the srsGUI library before building srsLTE:

https://github.com/srsLTE/srsGUI

The srsLTE source with instructions on how to compile and run it:

https://github.com/srsLTE/srsLTE

The srsLTE tools used in the simple example above is described here:

IMDEA-OWL

15.8 Terminating the Experiment

Resources that you hold in Powder are real, physical machines and are therefore limited and in high demand. When you are done, you should release them for use by other experimenters. Do this via the “Terminate” button on the Powder experiment status page.

screenshots/powder/powder-srs-16.png

Note: When you terminate an experiment, all data on the nodes is lost, so make sure to copy off any data you may need before terminating.

If you were doing a real experiment, you might need to hold onto the nodes for longer than the default expiration time. You would request more time by using the “Extend” button the on the status page. You would need to provide a written justification for holding onto your resources for a longer period of time.

15.9 Taking Next Steps

Now that you’ve got a feel for for what Powder can do, there are several things you might try next: