An information handling system includes a computing device, a computing component of the computing device that is housed in a chassis, and a chilled air filter that reduces a humidity level of a portion of an airflow when the chilled air filter is in an active state. The portion of the airflow thermally manages the computing component. The airflow is received by the chassis via an air receiving exchange and exhausted by the chassis via an air expelling exchange.

An information handling system includes a computing component that is sensitive to corrosion; and a chassis in which the computing component is disposed. The chassis receives an airflow used to thermally manage the computing component, and expels the airflow after thermally managing the computing component. The information handling system also includes an environmental control component that reduces a condensation formation propensity of a portion of the airflow that traverses the chassis proximate to the computing component.

Method and systems provide automated configuration of replaceable hardware components of a chassis comprising a plurality of IHSs (Information Handling Systems) and a plurality of storage devices that are configured to support demands of a specific computing solution designed for a particular computing task. The IHSs may be computing sleds and the storage devices may be storage sleds, where the sleds are coupled within bays of the chassis. Processes operating on the IHSs monitor for changes to settings related to the first computing solution. A chassis management controller detects updates to the replaceable hardware components that are coupled to the chassis and determines supported settings for detected new hardware components. Parameters for configuring the new hardware components for supporting the first computing solution are selected and used to configure the new hardware components.

Systems and methods for modernizing workspace and hardware lifecycle management in an enterprise productivity ecosystem are described. In some embodiments, a client Information Handling System (IHS) may include a processor, and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution by the processor, cause the client IHS to: transmit, by a local management agent to a workspace orchestration service, an access request and context information; receive, at the local management agent from the workspace orchestration service, one or more files or policies configured to enable the local management agent to instantiate a workspace based upon a workspace definition, wherein the workspace orchestration service is configured to: (i) calculate a security target and a productivity target based upon the access request and the context information, and (ii) create the workspace definition based upon the security target and the productivity target; and instantiate the workspace.

An apparatus for cooling warm air, including a rack containing one or more ventilation slots; a reservoir connected to the rack that contains a cooling solution; and a plurality of components, located within the rack, that receive and distribute the cooling solution from the reservoir. The plurality of components consist of at least one of the following structures: one or more hollow vertical louvers, one or more hollow horizontal louvers, one or more hollow diagonal louvers, and one or more hollow cylindrical louvers. Additionally, the plurality of components may comprise a flexible material that descends from a top portion of the rack, directly below the reservoir, at the same time that an activation component causes the cooling solution to flow from the reservoir into the flexible material.

Method and systems support configuring components of a chassis comprising a plurality of IHSs (Information Handling Systems). A management controller of the chassis initiates a process for identifying a plurality of hardware and software capabilities of the chassis. Based on the identified capabilities, computing solutions, such as specialized computation and storage functions, supported by the chassis are determined. The computing solutions supported by the capabilities of the chassis are encoded, such as within a set of compatibility bits. Upon detecting updates to the hardware and software capabilities of the chassis, the encoded compatibility bits are used to determine compatibility of the updated capabilities with computing solutions supported by the chassis. The encoded solution compatibility information is transmitted to a solution manager that monitors compliance of multiple chassis within a datacenter and identifies chassis that are compatible with a particular computing solution without querying the individual chassis.

In one or more embodiments, one or more systems, one or more methods, and/or one or more processes may determine an identification of an application executing on an information handling system (IHS); determine a first performance profile based at least on a policy and based at least on the identification of the application; configure a processor to utilize power up to a first power level based at least on the first performance profile; determine that a user physically utilizes at least one human input device of the IHS within an amount of time transpiring; receive information indicating that the user is physically in contact with the IHS; determine a second performance profile based at least on the policy and based at least on the information; and configure the processor to utilize power up to a second power level based at least on the second performance profile.

Methods and systems for ascertaining factors contributing to the temperature of a device. A method includes monitoring a plurality of parameters that are contributing to a temperature of the device. The method also includes estimating a degree of contribution of internal factors to the temperature of the device based on the monitored plurality of parameters and a battery temperature of a battery of the device. The method further includes estimating a degree of contribution of external factors to the temperature of the device, based on the monitored plurality of parameters and a battery temperature of a battery of the device. A neural network can be used for estimating the temperature of the ambience of the device and the impacts of internal and external factors on temperature of the device.

Systems, apparatuses and methods may provide for technology that includes a solid state drive (SSD) having an enclosure, a non-volatile memory (NVM) device, a device controller coupled the NVM device, a capacitor, a backup voltage line coupled to the capacitor, and a safety assembly. The safety assembly may include a timer circuit including an input node coupled to the backup voltage line, a reset node, and an output node, an indicator circuit coupled to the output node of the timer circuit, and a temperature comparator circuit coupled to the reset node of the timer circuit, wherein if a temperature of the enclosure exceeds a threshold while a backup voltage is present on the backup voltage line, the temperature comparator circuit causes the timer circuit to trigger light pulses from the indicator circuit.

Live process migration in response to real-time performance-based metrics is disclosed. At least one performance metric value that quantifies a performance metric of a first computing device is obtained. It is determined that the at least one performance metric value has an undesirable value. The initiation of a live migration of a process executing on the first computing device to a second computing device is caused based on determining that the at least one performance metric value has the undesirable value.