For best tracking results, you need to prepare and clean up the capture environment before setting up the system. First, remove unnecessary objects that could block the camera views. Cover open windows and minimize incoming sunlight. Avoid setting up a system over reflective flooring since IR lights from cameras may get reflected and add noise to the data. If this is not an option, use rubber mats to cover the reflective area. Likewise, items with reflective surfaces or illuminating features should be removed or covered with non-reflective materials in order to avoid extraneous reflections.

Ethernet Camera System

Ethernet Camera Models: Prime series and Slim 13E cameras. Follow the below wiring diagram and connect each of the required system components.

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Single PoE SwitchMultiple PoE Switch (Higher Camera Counts)

Single PoE Switch Setup

• PoE switch requirement: The PoE switches must be able to provide 15.4W power to every port simultaneously. Prime 17W, PrimeX 22, Prime 41, and PrimeX 41 camera models run on a high power mode to achieve longer tracking ranges, and they require 30W of power from each port. If you wish to operate these cameras at standard PoE mode, set the LLDP (PoE+) Detection setting to false under the application settings. For network switches provided by OptiTrack, refer to the label for the number of cameras supported for each switch.

• Connect PoE Switch(s) into the Host PC: Start by connecting a PoE switch into the host PC via an Ethernet cable. Since the camera system takes up a large amount of data bandwidth, the Ethernet camera network traffic must be separated from the office/local area network. If the computer used for capture is connected to an existing network, you will need to use a second Ethernet port or add-on network card for connecting the computer to the camera network. When you do, make sure to turn off your computer's firewall for the particular network under Windows Firewall settings.

• Connect the Ethernet Cameras to the PoE Switch(s): Ethernet cameras connect to the host PC via PoE/PoE+ switches using Cat 6, or above, Ethernet cables.

• Power the Switches: The switch must be powered in order to power the cameras. To completely shut down the camera system, the network switch needs to be powered off.

• Ethernet Cables: Ethernet cable connection is subject to the limitations of the PoE (Power over Ethernet) and Ethernet communications standards, meaning that the distance between camera and switch can go up to about 100 meters when using Cat 6 cables (Ethernet cable type Cat5e or below is not supported). For best performance, do not connect devices other than the computer to the camera network. Add-on network cards should be installed if additional Ethernet ports are required.

Ethernet Cable Requirements Cable Type There are multiple categories for Ethernet cables, and each has different specifications for maximum data transmission rate and cable length. For an Ethernet based system, category 6 or above Gigabit Ethernet cables should be used. 10 Gigabit Ethernet cables – Cat6e, Cat6a, and Cat7 — are recommended in conjunction with a 10 Gigabit uplink switch for the connection between the uplink switch and the host PC in order to accommodate for the high data traffic. Electromagnetic Shielding Also, please use a cable that has electromagnetic interference shielding on it. If cables without the shielding are used, cables that are close to each other could interfere and cause the camera to stall in Motive.

• External Sync: If you wish to connect external devices, use the eSync synchronization hub. Connect the eSync into one of the PoE switches using an Ethernet cable.

Multiple PoE Switch Setup for Higher Camera Counts

• Uplink Switch: For systems with higher camera counts that uses multiple PoE switches, use an uplink Ethernet switch to link and connect all of the switches to the Host PC. In the end, the switches must be connected in a star topology with the uplink switch at the central node connecting to the host PC. Never daisy chain multiple PoE switches in series because doing so can introduce latency to the system.

• High Camera Counts: For setting up more than 24 Prime series cameras, we recommend using a 10 Gigabit uplink switch and connecting it to the host PC via an Ethernet cable that supports 10 Gigabit transfer rate — Cat6a, Cat6e, and Cat7. This will provide larger data bandwidth and reduce the data transfer latency.

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See Also: Cabling and Wiring page.

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Optical motion capture systems utilize multiple 2D images from each camera to compute, or reconstruct, corresponding 3D coordinates. For best tracking results, cameras must be placed so that each of them captures unique vantage of the target capture area. Place the cameras circumnavigating around the capture volume, as shown in the example below, so that markers in the volume will be visible by at least two cameras at all times. Mount cameras securely onto stable structures (e.g. truss system) so that they don't move throughout the capture. When using tripods or camera stands, ensure that they are placed in stable positions. After placing cameras, aim the cameras so that their views overlap around the region where most of the capture will take place. Any significant camera movement after system calibration may require re-calibration. Cable strain-relief should be used at the camera end of camera cables to prevent potential damage to the camera.

In order to obtain accurate and stable tracking data, it is very important that all of the cameras are correctly focused to the target volume. This is especially important for close-up and long-range captures. For common tracking applications in general, focus-to-infinity should work fine, however, it is still important to confirm that each camera in the system is focused.

To adjust or to check camera focus, place some markers on the target tracking area. Then, set the camera to raw grayscale mode, increase the exposure and LED settings, and then Zoom onto one of the retroreflective markers in the capture volume and check the clarity of the image. If the image is blurry, adjust the camera focus and find the point where the marker is best resolved.

In order to properly run a motion capture system using Motive, the host PC must satisfy the minimum system requirements. Required minimum specifications vary depending on sizes of mocap systems and types of cameras used. Consult our Sale Engineers, or use the Build Your Own feature on our website to find out host PC specification requirements.

Motive is a software platform designed to control motion capture systems for various tracking applications. Motive not only allows the user to calibrate and configure the system, but it also provides interfaces for both capturing and processing of 3D data. The captured data can be recorded or live-streamed into other pipelines.

If you are new to Motive, we recommend you to read through Motive Basics page after going through this guide to learn about basic navigation controls in Motive.

Motive Activation Requirements

Host PC Requirements

Download and Install

To install Motive, simply download the Motive software installer for your operating system from the Motive Download Page, then run the installer and follow its prompts.

Note: Anti-virus software can interfere with Motive's ability to communicate with cameras or other devices, and it may need to be disabled or configured to allow the device communication to properly run the system.

License Activation Steps

1. Insert the USB Security Key into a USB-C port on the computer. If needed, you can also use a USB-A adapter to connect.
2. Launch Motive
3. Activate your software using the License Tool, which can be accessed in the Motive splash screen. You will need to input the License Serial Number and the Hash Code for your license.
4. After activation, the License tool will place the license file associated to the USB Security Key in the License folder. For more license activation questions, visit Licensing FAQs or contact our Support.

Notes on using USB Security Key When connecting the USB Security Key into the computer, please avoid sharing the USB card with other USB devices that may transmit a large amount of data frequently. For example, if you have external devices (e.g. Force Plates, NI-DAQ) that communicates via USB, connect those devices onto a separate USB card so that they don't interfere with the Security Key. USB Hardware Key from older version of Motive have been replaced by USB Security Key in Motive 3.x version or above.

Use the following controls for navigating throughout the 2D and 3D viewports in Motive. Most of the navigation controls are customizable, including both mouse actions and hotkeys. These mouse and keyboard controls can be customized through the Application Settings panel.

Now that the cameras are connected and showing up in Motive, the next step is to configure the camera settings. Appropriate camera settings will vary depending on various factors including the capture environment and tracked objects. The overall goal is to configure the settings so that the marker reflections are clearly captured and distinguished in the 2D view of each camera. For a detailed explanation on individual settings, please refer to the Devices pane page.

To check whether the camera setting is optimized, it is best to check both the grayscale mode images and tracking mode (Object or Precision) images and make sure the marker reflection stands out from the image. You switch a camera into grayscale mode either in Motive or by using the Aim Assist button for supported cameras. In Motive, you can right-click on the Cameras Viewport and switch the video mode in the context menu, or you can also change the video mode through the Properties pane.

Exposure Setting

Starting a Calibration

To start a system calibration, open the Calibration pane. Under the Calibration pane, you can choose to start a new calibration or to modify the existing one. For this guide, click New Calibration for a fresh calibration.

Starting a new calibration

Masking

Before the system calibration, any extraneous reflections or unnecessary markers should ideally be removed or covered so that they are not seen by the cameras. However, it may not always be possible to remove all of them. In this case, these extraneous reflections can be ignored by applying masks over them during the calibration.

1. Check the calibration pane to see if any of the cameras are seeing extraneous reflections or noise in their view. A warning sign will appear over these cameras.
2. Check the camera view of the corresponding camera to identify where the extraneous reflection is coming from, and if possible, remove them from the capture volume or cover them so that the cameras do not see them.
3. If reflections still exist, click Mask to automatically apply masks over all of the reflections detected in the camera views.
4. Once all of the reflections have been masked or removed, click Continue to proceed to the wanding step.

Masking in camera view.

Wanding

Performing calibration wanding for a systemwith 6 cameras

In the wanding stage, we will use the Calibration Wand to collect wanding samples that will be used for calibrating the system.

1. Set the Calibration Type to Full.
2. Under the Wand settings, specify the wand that you will be used to calibrate the volume. It is very important to input the matching wand size here. When an incorrect dimension is given to Motive, the calibrated 3D volume will be scaled incorrectly.
3. Click Start Wanding to start collecting the wanding sample.
4. Once the wanding process starts. Bring your calibration wand into the capture volume and start waving the wand gently across the entire capture volume. Gently draw figure-eight repetitively with the wand to collect samples at varying orientations and cover as much space as possible for sufficient sampling. Wanding trails will be shown in colors on the 2D View. A grid/table displaying the status of the wanding process will show up in the Calibration pane to monitor the progress.
5. As each camera collects the wanding samples, the camera grid representing the wanding status of each camera will start changing its color to bright green. This provides visual feedback on whether sufficient samples have been collected by each camera. Wave the wand until all boxes are filled with bright green color.
6. Once enough samples have been collected, press the Start Calculation button to start calibrating. The calculation may take a few minutes to complete.
7. When the calculation is finished, its results will get displayed. If the overall result is acceptable, click Continue to proceed to setting up the ground. If the result is not satisfactory, click Cancel and go through the wanding once more.

Wanding tips For best results, collect wand samples evenly and comprehensively throughout the volume, covering both low and high elevations. If you wish to start calibrating inside the volume, cover one of the markers and expose it wherever you wish to start wanding. When at least two cameras detect all the three markers while no other reflections are present in the volume, the wand will be recognized, and Motive will start collecting samples. Sufficient sample count for the calibration may vary for different sized volumes, but in general, collect 2500 ~ 6000 samples for each camera. Once a sufficient number of samples has been collected, press the button under the Calibration section. During the wanding process, each camera needs to see only the 3-markers on the calibration wand. If any of the cameras are detecting extraneous reflections, go back to the masking step to mask them.

Setting the Ground Plane

CS-400 calibration square.

Now that all of the cameras have been calibrated, the next step is to define the ground plane of the capture volume.

1. Place a Calibration Square inside the capture volume. Position the square so that the vertex marker is placed directly over the desired global origin.
2. Orient the calibration square so that the longer arm is directed towards the desired +Z axes and the shorter arm is directed towards the desired +X axes of the volume. Motive uses the y-up right-hand coordinate system.
3. Level the calibration square parallel to the ground plane.
4. At this point, the Calibration pane should detect which calibration square has been placed in the tracking volume. If not, you may want to specifically select the three markers on the calibration square from the 3D view in Motive.
5. Click Set Ground Plane to complete the calibration.

Motive Recordings

Motive Profiles

Place the retro-reflective markers onto subjects (rigid body or skeleton) that you wish to track. Double-check that the markers are attached securely. For skeleton tracking, open the Builder pane, go to skeleton creation options, and choose a marker set you wish to use. Follow the skeleton avatar diagram for placing the markers. If you are using a mocap suit, make sure that the suit fits as tightly as possible. Motive derives the position of each body segment from related markers that you place on the suit. Accordingly, it is important to prevent the shifting of markers as much as possible. Sample marker placements are shown below.

Tip: For creating trackable assets, click the Layout → Create menu item to access the model creation layout.

Create Rigid Body

Create Skeleton

Tip: For recording capture, access the Layout → Capture menu item, or the to access the capture layout

Once the volume is calibrated and skeletons are defined, now you are ready to capture. In the Control Deck at the bottom, press the dimmed red record button or simply press the spacebar when in the Live mode to begin capturing. This button will illuminate in bright red to indicate recording is in progress. You can stop recording by clicking the record button again, and a corresponding capture file (TAK extension), also known as capture Take, will be saved within the current session folder. Once a Take has been saved, you can playback captures, reconstruct, edit, and export your data in a variety of formats for additional analysis or use with most 3D software.

When tracking skeletons, it is beneficial to start and end the capture with a T-pose. This allows you to recreate the skeleton in post-processing when needed.

After capturing a Take. Recorded 3D data and its trajectories can be post-processed using the Data Editing tools, which can be found in the Edit Tools Pane. Data editing tools provide post-processing features such as deleting unreliable trajectories, smoothing select trajectories, and interpolating missing (occluded) marker positions. Post-editing the 3D data can improve the quality of tracking data.

Tip: For data editing, access the Layout → Edit menu item, or the to access the capture layout

General Editing Steps

1. Skim through the overall frames in a Take to get an idea of which frames and markers need to be cleaned up.
2. Refer to the Labels pane and inspect gap percentages in each marker.
3. Select a marker that is often occluded or misplaced.
4. Look through the frames in the Graph pane, and inspect the gaps in the trajectory.
5. For each gap in frames, look for an unlabeled marker at the expected location near the solved marker position. Re-assign the proper marker label if the unlabeled marker exists.
6. Use Trim Tails feature to trim both ends of the trajectory in each gap. It trims off a few frames adjacent to the gap where tracking errors might exist. This prepares occluded trajectories for Gap Filling.
7. Find the gaps to be filled, and use the Fill Gaps feature to model the estimated trajectories for occluded markers.
8. Re-Solve assets to update the solve from the edited marker data

Markers detected in the camera views get trajectorized into 3D coordinates. The reconstructed markers need to be labeled for Motive to distinguish different trajecectories within a capture. Trajectories of annotated reconstructions can be exported individually or used (solved altogether) to track the movements of the target subjects. Markers associated with Rigid Bodies and Skeletons are labeled automatically through the auto-labeling process. Note that rigid body and skeleton markers can be auto-labeled both during Live mode (before capture) and Edit mode (after capture). Individual markers can also be labeled, but each marker needs to be manually labeled in post-processing using assets and the Labeling pane. These manual Labeling tools can also be used to correct any labeling errors. Read through the Labeling page for more details in assigning and editing marker labels.

• Auto-label: Automatically label sets of rigid body markers and skeleton markers using the corresponding asset definitions.
• Manual Label: Labeling individual markers manually using the Labeling pane, assigning labels defined in the Marker Set, rigid body, or skeleton assets.

Changing Marker Labels and Colors When needed, you can use the Constraints pane to adjust marker labels for both rigid body and skeleton markers. You can also adjust markers sticks and marker colors as needed.

Motive exports reconstructed 3D tracking data in various file formats, and exported files can be imported into other pipelines to further utilize capture data. Supported formats include CSV and C3D for Motive: Tracker, and additionally, FBX, BVH, and TRC for Motive: Body. To export tracking data, select a Take to export and open the export dialog window, which can be accessed from File → Export Tracking Data or right-click on a Take → Export Tracking data from the Data pane. Multiple Takes can be selected and exported from Motive or by using the Motive Batch Processor. From the export dialog window the frame rate, measurement scale, and frame range of exported data can be configured. Frame ranges can also be specified by selecting a frame range in the Graph pane before exporting a file. In the export dialog window, corresponding export options are available for each file format.

Motive offers multiple options to stream tracking data onto external applications in real-time. Tracking data can be streamed in both Live mode and Edit mode. Streaming plugins are available for Autodesk Motion Builder, Visual3D, The MotionMonitor, Unreal Engine 4, 3ds Max, Maya (VCS), and VRPN, and they can be downloaded from the OptiTrack website. For other streaming options, the NatNet SDK enables users to build custom client and server applications to stream capture data. Common motion capture applications rely on real-time tracking, and the OptiTrack system is designed to deliver data at an extremely low latency even when streaming to third-party pipelines. Detailed instructions on specific streaming protocols are included in the PDF documentation that ships with the respective plugins or SDK's.