Software Functional Overview

The result is an integer value that describes up to 0.1 precisions in Kelvin. For example, 300.0K are represented by the integer 3000.

z_PSL

This object evaluates to a list of processor objects to be used for Passive cooling.

z_PSV

This control method returns the temperature at which the OS must activate CPU throttling.

Arguments: None.

Result Code: Temperature in tenths Kelvin.

The result code is an integer value that describes up to 0.1 precision in Kelvin. For example, 300.0 Kelvin is represented by 3000.

z_SCP

This control method notifies the hardware of the current user cooling mode setting. The hardware can use this as a trigger to reassign _ACx and _PSV temperatures. The operating system will automatically evaluate _ACx and _PSV objects after executing _SCP.

Arguments: 0 - Active; 1 - Passive

Result Code: None.

z_TC1

This is a thermal object that evaluates to the constant _ TC1 for use in the Passive cooling formula:

ΔPerformance [%]= _TC2 * ( Tn - Tn-1 ) + _TC1 * (Tn. - Tt)

z_TC2

This is a thermal object that evaluates to the constant _TC2 for use in the Passive cooling formula:

ΔPerformance [%]= _TC2 * ( Tn - Tn-1 ) + _TC1 *.(Tn. - Tt)

z_TMP

This control method returns the thermal zone

current operating temperature in Kelvin.

Argument: None.

Result Code: Temperature in tenths Kelvin.

The result is an integer value that describes up to 0.1 precision in Kelvin. For example, 300.0K is represented by the integer 3000.

z_TSP

This is an object that evaluates to a thermal sampling period used by the OS to implement the Passive cooling equation. This value, along with _TC1 and _TC2, will enable the OS to provide the proper hysteresis required by the system to accomplish an effective passive cooling policy. The granularity of the sampling period is 0.1second. For example, if the sampling period is 30.0 seconds, then _TSP needs to report 300; if the sampling period is 0.5 seconds, then it will report 5. The OS can normalize the sampling over a longer period if

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FIC M296, M295 service manual Psv, Scp, TC1, TC2, Tmp, Tsp

M296, M295 specifications

The FIC M295 and M296 are modern military vehicles designed for versatility, durability, and efficiency in various operational environments. Both models have gained attention for their advanced features and technological integrations, making them suitable for a range of missions, including logistics, reconnaissance, and troop transport.

One of the standout features of the FIC M295 and M296 is their modular design. This allows for easy configuration based on specific mission requirements. Whether deployed in urban settings or rugged terrains, these vehicles can be outfitted with different payloads and weaponry, enhancing their adaptability and usability. The modularity extends to interior configurations, offering flexibility in troop transport or cargo capacity.

The M295 boasts a robust powertrain, equipped with a high-torque engine that provides excellent off-road capability. Coupled with advanced suspension systems, the vehicle can traverse difficult landscapes while maintaining stability and comfort for its occupants. The M296, on the other hand, offers a slightly different engine configuration, focusing on fuel efficiency without compromising power. Both models are engineered to operate in extreme temperatures and harsh conditions, ensuring reliability in the field.

Another key characteristic is the advanced communication and navigation systems integrated into both vehicles. They come equipped with state-of-the-art GPS and real-time data transmission capabilities, allowing for seamless coordination with commanding units. Furthermore, enhanced battlefield awareness features, such as advanced sensor packages, provide operators with critical information about their surroundings, improving situational awareness and decision-making.

Protection is a fundamental aspect of the FIC M295 and M296. Both models include reinforced armor plating designed to withstand various ballistic threats. Additionally, they incorporate an advanced heat management system to minimize vulnerability to thermal detection by enemy forces. The vehicles also offer options for further armoring and countermeasure systems to enhance safety during operations.

The ergonomics of the cockpit and crew compartment have been meticulously designed to enhance operator comfort and efficiency. Controls are intuitive, and ample space is provided for gear and equipment, making the M295 and M296 not only practical but user-friendly.

In conclusion, the FIC M295 and M296 represent a significant advancement in military vehicle technology. Their combination of modularity, advanced propulsion systems, superior communication capabilities, and robust protection measures makes them an excellent choice for modern warfare scenarios. These vehicles embody the balance of strength, adaptability, and cutting-edge technology that contemporary military operations demand.