# Perception Tutorial ## Phase 3: Cloud In this phase of the tutorial, we will learn how to run our Scene on _**Unity Simulation**_ and analyze the generated dataset using _**Dataset Insights**_. Unity Simulation will allow us to generate a much larger dataset than what is typically plausible on a workstation computer. Steps included this phase of the tutorial: - [Step 1: Setup Unity Account, Unity Simulation, and Cloud Project](#step-1) - [Step 2: Run Project on Unity Simulation](#step-2) - [Step 3: Keep Track of Your Runs Using the Unity Simulation Command-Line Interface](#step-3) - [Step 4: Analyze the Dataset using Dataset Insights](#step-4) ### Step 1: Setup Unity Account, Unity Simulation, and Cloud Project In order to use Unity Simulation, you need to first create a Unity account or login with your existing one. Once logged in, you will also need to sign-up for Unity Simulation. * **:green_circle: Action** Click on the _**Cloud**_ button at the top-right corner of Unity Editor to open the _**Services**_ tab.
If you have not logged in yet, the _**Services**_ tab will display a message noting that you are offline:
* **:green_circle: Action**: Click _**Sign in...**_ and follow the steps in the window that opens to sign in or create an account. * **:green_circle: Action**: Sign up for a free trial of Unity Simulation [here](https://unity.com/products/unity-simulation). Unity Simulation is a cloud-based service that makes it possible for you to run hundreds of instances of Unity builds in order to generate massive amounts of data. The Unity Simulation service is billed on a per-usage basis, and the free trial offers up to $100 of free credit per month. In order to access the free trial, you will need to provide credit card information. **This information will be used to charge your account if you exceed the $100 monthly credit.** A list of hourly and daily rates for various computational resources is available in the page where you first register for Unity Simulation. Once you have registered for a free trial, you will be taken to your Unity Simulation dashboard, where you will be able to observe your usage and billing invoices. It is now time to connect your local Unity project to a cloud project. * **:green_circle: Action**: Return to Unity Editor. In the _**Services**_ tab click _**Select Organization**_ and choose the only available option (which typically has the same name as your Unity username). If you have used Unity before, you might have set-up multiple organizations for your account. In that case, choose whichever you would like to associate with this project.
* **:green_circle: Action**: Click _**Create**_ to create a new cloud project and connect your local project to it. ### Step 2: Run Project on Unity Simulation The process of running a project on Unity Simulation involves building it for Linux and then uploading this build, along with a set of parameters, to Unity Simulation. The Perception package simplifies this process by including a dedicated _**Run in Unity Simulation**_ window that accepts a small number of required parameters and handles everything else automatically. For performance reasons, it is best to disable real-time visualizations before carrying on with the Unity Simulation run. * **:green_circle: Action**: From the _**Inspector**_ view of `Perception Camera`, disable real-time visualizations. In order to make sure our builds are compatible with Unity Simulation, we need to set our project's scripting backend to _**Mono**_ rather than _**IL2CPP**_ (if not already set). We will also need to switch to _**Windowed**_ mode. * **:green_circle: Action**: From the top menu bar, open _**Edit -> Project Settings**_. * **:green_circle: Action**: In the window that opens, navigate to the _**Player**_ tab, find the _**Scripting Backend**_ setting (under _**Other Settings**_), and change it to _**Mono**_:
* **:green_circle: Action**: Change _**Fullscreen Mode**_ to _**Windowed**_ and set a width and height of 800 by 600.
* **:green_circle: Action**: Close _**Project Settings**_. * **:green_circle: Action**: From the top menu bar, open _**Window -> Run in Unity Simulation**_.
* **:green_circle: Action**: Choose `TutorialScene` (which is the Scene we have been working in) as your _**Main Scene**_ and the `SimulationScenario` object as your _**Scenario**_. Here, you can also specify a name for the run, the number of iterations the Scenario will execute for, and the number of _**Instances**_ (number of nodes the work will be distributed across) for the run. * **:green_circle: Action**: Name your run `FirstRun`, set the number of iterations to `1000`, and instances to `20`. * **:green_circle: Action**: Click _**Build and Run**_. Your project will now be built and then uploaded to Unity Simulation. Depending on the upload speed of your internet connection, this might take anywhere from a few seconds to a couple of minutes. * **:green_circle: Action**: Once the operation is complete, you can find the **Build ID**, **Run Definition ID**, and **Execution ID** of this Unity Simulation run in the _**Console**_ tab:
### Step 3: Keep Track of Your Runs Using the Unity Simulation Command-Line Interface To keep track of the progress of your Unity Simulation run, you will need to use Unity Simulation's command-line interface (CLI). Detailed instructions for this CLI are provided [here](https://github.com/Unity-Technologies/Unity-Simulation-Docs/blob/master/doc/quickstart.md#download-unity-simulation-quickstart-materials). For the purposes of this tutorial, we will only go through the most essential commands, which will help us know when our Unity Simulation run is complete and where to find the produced dataset. * **:green_circle: Action**: Download the latest version of `unity_simulation_bundle.zip` from [here](https://github.com/Unity-Technologies/Unity-Simulation-Docs/releases). > :information_source: If you are using a MacOS computer, we recommend using the _**curl**_ command from the Terminal to download the file, in order to avoid issues caused by the MacOS Gatekeeper when using the CLI. You can use these commands: ``` curl -Lo ~/Downloads/unity_simulation_bundle.zip
> :warning: On MacOS, you might get errors related to permissions. If that is the case, modify the permissions on the `~/.usim` folder and its contents to give your user full read and write permission. > :information_source: From this point on we will only include MacOS formatted commands in the tutorial, but all the `usim` commands we use will work in all supported operating systems.** * **:green_circle: Action**: Return to your command-line interface. Get a list of cloud projects associated with your Unity account using the `usim get projects` command: MacOS: `USimCLI/mac/usim get projects` Example output: ``` name id creation time --------------------- ---------------------------------------- --------------------------- Perception Tutorial acd31956-582b-4138-bec8-6670be150f09 * 2020-09-30T00:33:41+00:00 SynthDet 9ec23417-73cd-becd-9dd6-556183946153 2020-08-12T19:46:20+00:00 ``` In case you have more than one cloud project, you will need to "activate" the one corresponding with your perception tutorial project. If there is only one project, it is already activated, and you will not need to execute the command below (note: replace `
The next few lines of code pertain to setting up your notebook for downloading data from Unity Simulation. * **:green_circle: Action**: In the block of code titled "Unity Simulation [Optional]", uncomment the lines that assign values to variables, and insert the correct values, based on information from your Unity Simulation run. We have previously learned how to obtain the `run_execution_id` and `project_id`. You can remove the value already present for `annotation_definition_id` and leave it blank. What's left is the `access_token`. * **:green_circle: Action**: Return to your command-line interface and run the `usim inspect auth` command. MacOS: `USimCLI/mac/usim inspect auth` If you receive errors regarding authentication, your token might have timed out. Repeat the login step (`usim login auth`) to login again and fix this issue. A sample output from `usim inspect auth` will look like below: ``` Protect your credentials. They may be used to impersonate your requests. access token: Bearer 0CfQbhJ6gjYIHjC6BaP5gkYn1x5xtAp7ZA9I003fTNT1sFp expires in: 2:00:05.236227 expired: False refresh token: FW4c3YRD4IXi6qQHv3Y9W-rwg59K7k0Te9myKe7Zo6M003f.k4Dqo0tuoBdf-ncm003fX2RAHQ updated: 2020-10-02 14:50:11.412979 ``` The `access_token` you need for your Dataset Insights notebook is the access token shown by the above command, minus the `'Bearer '` part. So, in this case, we should input `0CfQbhJ6gjYIHjC6BaP5gkYn1x5xtAp7ZA9I003fTNT1sFp` in the notebook. * **:green_circle: Action**: Copy the access token excluding the `'Bearer '` part to the corresponding field in the Dataset Insights notebook. Once you have entered all the information, the block of code should look like the screenshot below (the actual values you input will be different):
* **:green_circle: Action**: Continue to the next code block and run it to download all the metadata files from the generated dataset. This includes JSON files and logs but does not include images (which will be downloaded later). You will see a progress bar while the data downloads:
The next couple of code blocks (under "Load dataset metadata") analyze the downloaded metadata and display a table containing annotation-definition-ids for the various metrics defined in the dataset. * **:green_circle: Action**: Once you reach the code block titled "Built-in Statistics", make sure the value assigned to the field `rendered_object_info_definition_id` matches the id displayed for this metric in the table output by the code block immediately before it. The screenshot below demonstrates this (note that your ids might differ from the ones here):
Follow the rest of the steps inside the notebook to generate a variety of plots and stats. Keep in mind that this notebook is provided just as an example, and you can modify and extend it according to your own needs using the tools provided by the [Dataset Insights framework](https://datasetinsights.readthedocs.io/en/latest/). This concludes the Perception tutorial. The next step in this workflow would be to train an object-detection model using a dataset generated on Unity Simulation. It is important to note that the 1000 large dataset we generated here is probably not sufficiently large for training most models. We chose this number here so that the run would complete in a fairly short period of time, allowing us to move on to learning how to analyze the dataset's statistics. In order to generate data for training, we recommend a dataset of about 400,000 captures. In the near future, we will expand this tutorial to Phase 4, which will include instructions on how to train a Faster R-CNN object-detection model using a dataset that can be generated by following this tutorial.