Abstract: One variation of a method—for controlling a breathing mask comprising a flow control module configured to mate to nostrils of a user and comprising an actuator configured to adjust obstruction to airflow out of the flow control module—includes: accessing a wake alarm time; accessing a sleep delay duration; at a first time, receiving an indicator that the user is preparing for sleep; in response to receiving the indicator, triggering the actuator to transition from a minimum-restriction position toward a maximum-restriction position at a second time succeeding the first time by the sleep delay duration, the actuator minimally obstructing airflow out of outlet port in the minimum-restriction position and maximally obstructing airflow out of outlet port in the maximally-restriction position; and, prior to the wake alarm time, triggering the actuator to transition back to the minimum-restriction position.

Abstract: The present disclosure relates to systems for providing information in an automated or semi-automated manner, through use of one or more autonomous virtual analysts. In one embodiment, the autonomous virtual analysts may perform many of the same functions as a human analyst, and provide business intelligence relating to revenue, income, profit, loss, expenses, historical data, projections, trends, comparative analysis, etc. In embodiments, the autonomous virtual analyst may be employed through use of natural language dialog with a user, and further configured to capture and appropriately respond to the context of the dialog by supplying a user with information pertinent to the request. According to varying embodiments, a variety of decision trees comprising a plurality of nodes is disclosed. In varying embodiments, the system may comprise one or more distinct modules, including a driver graph module.

Abstract: An information handling system (IHS), peripheral component interface (PCI) system and method for expanding PCI nodes in an IHS. The PCI system includes a primary PCI node. The primary PCI node has a PCI switch communicatively coupled to a processor via a system interconnect. The PCI switch is communicatively coupled to several PCI devices. A communication module is communicatively coupled to the PCI switch. A PCI expansion node is communicatively coupled to the primary PCI node via a PCI bus and a sideband bus. The IHS executes firmware that enables expansion of the IHS by configuring the primary PCI node to recognize the one or more interconnected PCI expansion nodes and integrate the functions of the interconnected PCI expansion nodes into an expanded PCI subsystem. The primary PCI node and PCI expansion node can be substantially identical IHSs, having the same motherboards and chassis.

Abstract: Described herein is an automated method for the preparation of an accident profile or notice of loss as part of an insured claim submission.

Abstract: One variation of a method—for controlling a breathing mask comprising a flow control module configured to mate to nostrils of a user and comprising an actuator configured to adjust obstruction to airflow out of the flow control module—includes: accessing a wake alarm time; accessing a sleep delay duration; at a first time, receiving an indicator that the user is preparing for sleep; in response to receiving the indicator, triggering the actuator to transition from a minimum-restriction position toward a maximum-restriction position at a second time succeeding the first time by the sleep delay duration, the actuator minimally obstructing airflow out of outlet port in the minimum-restriction position and maximally obstructing airflow out of outlet port in the maximally-restriction position; and, prior to the wake alarm time, triggering the actuator to transition back to the minimum-restriction position.

Abstract: One variation of a dynamic tactile interface includes: a dynamic tactile layer including a deformable region and a first region, the deformable region operable between a retracted setting and an expanded setting, the first region adjacent the deformable region, the deformable region tactilely distinguishable from the first region in the expanded setting; a displacement device including a fluid vessel and an actuator, the actuator displacing fluid from the fluid vessel into the dynamic tactile layer to transition the deformable region from the retracted setting into the expanded setting and displacing fluid from the dynamic tactile layer into the fluid vessel, transitioning the deformable region from the expanded setting into the retracted setting; and a fluid compensation device coupled to the displacement device and adjusting a configuration of the displacement device in response to a change in a volume of fluid contained within the fluid vessel.

Abstract: One variation of a dynamic tactile interface includes: a tactile layer including a deformable region and a peripheral region adjacent the deformable region; a substrate coupled to the tactile layer, the substrate defining fluid channel and cooperating with the deformable region to define a variable volume fluidly coupled to the fluid channel; a displacement device coupled to the bladder, displacing fluid into the variable volume to transition the deformable region from the retracted setting to the expanded setting, and displacing fluid out of the variable volume to transition the deformable region from the expanded setting to the retracted setting, the displacement device defining a equilibrium range of fluid pressures within the fluid channel; a reservoir fluidly coupled to the fluid channel and supporting a reserve volume of fluid; and a valve selectively controlling transfer of fluid from the reservoir to the fluid channel.

Abstract: One variation of a dynamic tactile interface includes: a substrate including a first transparent material and defining an attachment surface, an open channel opposite the attachment surface, and a fluid conduit intersecting the open channel and passing through the attachment surface; a tactile layer including a second transparent material and defining a tactile surface, a peripheral region bonded to the attachment surface opposite the tactile surface, and a deformable region adjacent the fluid conduit and disconnected from the attachment surface; a closing panel bonded to the substrate opposite the attachment surface and enclosing the open channel to define a fluid channel; a working fluid; and a displacement device configured to displace the working fluid into the fluid channel and through the fluid conduit to transition the deformable region from a retracted setting to an expanded setting.

Abstract: One variation of a dynamic tactile interface includes a tactile layer defining a peripheral region and a deformable region adjacent the peripheral region; a substrate coupled to the peripheral region, a fluid conduit adjacent the deformable region, a fluid channel fluidly coupled to the fluid conduit, and a via fluidly coupled to the fluid channel and passing through the back surface; a bladder fluidly coupled to the via and the substrate; a structure adjacent a first side of the bladder; and a platen adjacent a second side of the bladder opposite the first side and compressing the bladder against the structure substantially perpendicular the longitudinal axis of the bladder and substantially parallel the substrate to displace fluid from the bladder and into the fluid channel to transition the deformable region from a retracted setting into an expanded setting.

Abstract: A dynamic tactile interface includes a tactile layer including a peripheral region and a deformable region adjacent the peripheral region, the deformable region operable between an expanded setting and a retracted setting; a substrate coupled to the peripheral region and defining a fluid conduit and a fluid channel fluidly coupled to the fluid conduit, the fluid conduit adjacent the deformable region; and a spring element coupled to the substrate between the tactile layer and the substrate, arranged substantially over the fluid conduit, and operable in a first distended position and a second distended position, the spring element at a local minimum of potential energy in the expanded setting and in the first distended position and at a second potential energy greater than the local minimum of potential energy between the first distended position and the second distended position, the spring element defining a nonlinear displacement response to an input displacing the deformable region in the expanded setting

Abstract: One variation of a dynamic tactile interface includes: a substrate defining a fluid channel and a fluid conduit fluidly coupled to the fluid channel; a tactile layer comprising a peripheral region and a deformable region, the peripheral region coupled to the substrate, and the deformable region arranged over the fluid conduit, disconnected from the substrate, and operable between a retracted setting and an expanded setting, the deformable region elevated above the peripheral region in the expanded setting; a tube comprising a first end fluidly coupled to the fluid channel and constrained relative to the substrate; a volume of fluid within the tube; and a rotary actuator coupled to the tube remote from the first end and configured to transition the deformable region from the retracted setting to the expanded setting by winding the tube to displace a portion of the volume of fluid within the tube into the fluid channel.

Abstract: A dynamic tactile interface including a tactile layer defining a first region and a deformable region adjacent the first region; a substrate coupled to the tactile layer at the first region, defining a variable volume adjacent the deformable region and defining a fluid channel fluidly coupled to the variable volume; a set of rigid structures distributed across the tactile layer defining an anti-reflective coating over the tactile layer; and a displacement device fluidly coupled to the fluid channel, the displacement device displacing fluid into the fluid channel to transition the deformable region from a retracted setting to an expanded setting, the deformable region tactilely distinguishable from the first region in the expanded setting, the set of rigid structures conforming to the tactile layer, each rigid structure in the set of rigid structures shifting relative to an adjacent rigid structure in the set of rigid structures.

Abstract: A dynamic tactile interface includes: a substrate including a first transparent material and defining an attachment surface, an open channel opposite the attachment surface, and a fluid conduit intersecting the open channel and passing through the attachment surface; a tactile layer including a second transparent material and defining a tactile surface, a peripheral region bonded to the attachment surface opposite the tactile surface, and a deformable region adjacent the fluid conduit and disconnected from the attachment surface; a closing panel bonded to the substrate opposite the attachment surface and enclosing the open channel to define a fluid channel; a working fluid; and a displacement device configured to displace the working fluid into the fluid channel and through the fluid conduit to transition the deformable region from a retracted setting to an expanded setting.

Abstract: One variation of a dynamic tactile interface includes a tactile layer defining a peripheral region and a deformable region adjacent the peripheral region; a substrate coupled to the peripheral region, a fluid conduit adjacent the deformable region, a fluid channel fluidly coupled to the fluid conduit, and a via fluidly coupled to the fluid channel and passing through the back surface; a bladder fluidly coupled to the via and the substrate; a structure adjacent a first side of the bladder; and a platen adjacent a second side of the bladder opposite the first side and compressing the bladder against the structure substantially perpendicular the longitudinal axis of the bladder and substantially parallel the substrate to displace fluid from the bladder and into the fluid channel to transition the deformable region from a retracted setting into an expanded setting.

Abstract: A wide area printer is capable of printing large images on non-typical surfaces such as pavement, grass, or soil. The printer is a wheeled device that is capable of multiple configurations including a plurality of drop nozzle arrays and a plurality of spray nozzle arrays. Each nozzle is independently addressable. Alternately, a group of nozzles may be addressed simultaneously. Each array of nozzles contains a carrier and a colorant. The colorant may be pre-mixed in the carrier, or may be mixed in-situ.

Abstract: One variation of a dynamic tactile interface includes: a substrate including a first transparent material and defining an attachment surface, an open channel opposite the attachment surface, and a fluid conduit intersecting the open channel and passing through the attachment surface; a tactile layer including a second transparent material and defining a tactile surface, a peripheral region bonded to the attachment surface opposite the tactile surface, and a deformable region adjacent the fluid conduit and disconnected from the attachment surface; a closing panel bonded to the substrate opposite the attachment surface and enclosing the open channel to define a fluid channel; a working fluid; and a displacement device configured to displace the working fluid into the fluid channel and through the fluid conduit to transition the deformable region from a retracted setting to an expanded setting.

Abstract: One variation of a dynamic tactile interface includes: a dynamic tactile layer including a deformable region and a first region, the deformable region operable between a retracted setting and an expanded setting, the first region adjacent the deformable region, the deformable region tactilely distinguishable from the first region in the expanded setting; a displacement device including a fluid vessel and an actuator, the actuator displacing fluid from the fluid vessel into the dynamic tactile layer to transition the deformable region from the retracted setting into the expanded setting and displacing fluid from the dynamic tactile layer into the fluid vessel, transitioning the deformable region from the expanded setting into the retracted setting; and a fluid compensation device coupled to the displacement device and adjusting a configuration of the displacement device in response to a change in a volume of fluid contained within the fluid vessel.

Abstract: A dynamic tactile interface includes a dynamic tactile layer and a manual fluid actuator. The manual fluid actuator includes a displacement device including a bladder, a platen adjacent the bladder, an elongated member coupled to the platen, and a rotary actuator, the elongated member and the rotary actuator translating rotation of the rotary actuator into translation of the platen, the platen compressing the bladder in response to rotation of the rotary actuator in a first direction and expanding the bladder in response to rotation of the rotary actuator in a second direction opposite the first direction.

Abstract: Input is detected on a dynamic tactile interface based on pressure events and touch sensor outputs. The dynamic tactile interface includes a touch sensor, a pressure sensor, and a compressible material. When both a pressure event and touch sensor output are correlated to identify an input, the input is processed by a display device associated with the dynamic tactile interface. The flexible material may be implemented as a variable volume associated with a deformable region, such that when the deformable region is depressed the variable volume decreases and the pressure sensor detects increased pressure. The flexible material may be implemented as a compressible layer between two layers that comprise the touch sensor, such that when an input is received on an upper layer of the touch sensor, the middle layer having the flexible volume may compress. The multi-layer touch sensor can be a capacitance touch or resistive touch sensor.