A method for providing haptic feedback to participants of multi-party phone conversations that includes opening a communications session with a conference system for at least two users each having user specific communications devices, user specific conduct measuring devices, and user specific haptic feedback device registered with the conference system. Analyzing content of the communications session from content received by the conference system through the user specific communications device for at least one of the users; and capturing status for said at least two users from data measured by the user specific conduct measuring device for the at least two users. Determining with the conference system if the content of the communications session and the status of said at least two users calls for input by the user through said user specific communications device. Sending a feedback signal from the conference system to the user specific haptic feedback device.

Electronic conferences often comprise a mixture of on-site and remote participants. A moderator may selectively engage remote participants for full-duplex interactions, such in response to the remote participant “raising their hand” to signal a question or desire to speak. Systems and methods are provided to enable a moderator to utilize natural speech to be utilized as voice commands, and with no other input, to cause a remote participant to be unmuted, enabling full-duplex for the associated remote terminal, and when the question is done, re-muted and thereby returned to half-duplex.

Methods, systems and computer program products are provided for aggregating active speaker channels, receiving, through an input interface, a selection of a solo speaker channel representing one of the plurality of speaker channels and setting the audio level of any one of the solo speaker channel and at least one non-solo speaker channel, or a combination of both the solo speaker channel and the at least one non-solo speaker channel.

The disclosed techniques improve user engagement and promote efficient use of computing resources by providing dynamically controlled aspect ratios for communication session renderings based on a physical orientation of a device. In some configurations, a system can select a first aspect ratio for individual video streams of a communication session when a device is in a first orientation, e.g., a portrait orientation. In addition, the system can select a second aspect ratio for the individual video streams when the device is in a second orientation, e.g., a landscape orientation. In some configurations, the first aspect ratio can be greater than the second aspect ratio, or the aspect ratios can be selected based on a target aspect ratio, which can be adjusted over time. By dynamically selecting an aspect ratio for individual stream renderings, screen space of a device can be optimized while the device is held in various physical orientations.

While a teleconference is occurring, data of a teleconference is analyzed to determine first participant data associated with a first speaker and second participant data associated with a second speaker. At a different application, addition of a first speaker indicator and a second speaker indicator to a text entry of a user is caused, the first speaker indicator added concurrently with identification that the first speaker is speaking and the second speaker indicator added concurrently with identification that the second speaker is speaking. At the different application, addition of key information to a text entry of a user is caused, the key information comprising participant data associated with the first speaker and second participant data associated with the second speaker.

The disclosed techniques improve user engagement and promote efficient use of computing resources by providing dynamically controlled aspect ratios for communication session renderings based on a physical orientation of a device. In some configurations, a system can select a first aspect ratio for individual video streams of a communication session when a device is in a first orientation, e.g., a portrait orientation. In addition, the system can select a second aspect ratio for the individual video streams when the device is in a second orientation, e.g., a landscape orientation. In some configurations, the first aspect ratio can be greater than the second aspect ratio, or the aspect ratios can be selected based on a target aspect ratio, which can be adjusted over time. By dynamically selecting an aspect ratio for individual stream renderings, screen space of a device can be optimized while the device is held in various physical orientations.

The disclosed techniques improve user engagement and promote efficient use of computing resources by providing dynamically controlled aspect ratios for communication session renderings based on a physical orientation of a device. In some configurations, a system can select a first aspect ratio for individual video streams of a communication session when a device is in a first orientation, e.g., a portrait orientation. In addition, the system can select a second aspect ratio for the individual video streams when the device is in a second orientation, e.g., a landscape orientation. In some configurations, the first aspect ratio can be greater than the second aspect ratio, or the aspect ratios can be selected based on a target aspect ratio, which can be adjusted over time. By dynamically selecting an aspect ratio for individual stream renderings, screen space of a device can be optimized while the device is held in various physical orientations.

Examples disclosed herein provide the ability for a computing device to configure one microphone at a time from physically colocated devices to remain active for participating in a teleconference. In one example method, the computing device determines whether a first device with a first microphone on the teleconference is physically colocated with respect to a second device with a second microphone on the teleconference. When the first and second devices are physically colocated with respect to each other, the computing device configures either the first or second microphone to remain active for participating in the teleconference while the other of the first or second microphone is to be muted.

Methods, systems and computer program products are provided for aggregating a active speaker channels, receiving, through an input interface, a selection of a solo speaker channel representing one of the plurality of speaker channels and setting the audio level of any one of the solo speaker channel and at least one non-solo speaker channel, or a combination of both the solo speaker channel and the at least one non-solo speaker channel.

Embodiments allow for an auto-mixer to gate microphones on and off based on speech detection, without losing or discarding the speech received during the speech recognition period. An example method includes receiving and storing an input audio signal. The method also includes determining, based on a first segment of the input audio signal, that the input audio signal comprises speech, and determining a delay between the input audio signal and a corresponding output audio signal provided to a speaker. The method also includes reducing the delay, wherein reducing the delay comprises removing one or more segments of the stored input audio signal to create a time-compressed audio signal and providing the time-compressed audio signal as the corresponding output audio signal. The method also includes determining that the delay is less than a threshold duration, and responsively providing the input audio signal as the corresponding output audio signal.