Toolkit For Android Free [UPDATED] Download

You can easily create different android emulator images that mimic the different hardware and software features of the devices available. Like said above there are some available from the manufacturers for download (e.g. Samsung Galaxy Tab, B&N Nook Color, Cisco Cius, Motorola and so on) and with a bit of googling you can create ones for other devices easily as well. All you need is the phones datasheet.

TECHNOLOGY AREA(S): Bio Medical OBJECTIVE: The objective of this topic is to develop and demonstrate a robust and ruggedized mobile causality display toolkit for Tactical Combat Casualty Care (TC3). DESCRIPTION: This topic seeks the development of a mobile causality display toolkit prototype for use on any mobile device with Bluetooth technology to provide medics and CLSs with a more in-depth TC3 training in live exercises. This new solution for representing causality injuries will enable self, buddy, Combat Livesafer (CLS), and medic care in live exercises and address the need to increase infantry squad capabilities to improve tactical effectiveness while managing casualties. The components of this toolkit will include an android mobile device and tools that support care of preventable deaths. All components of the toolkit should withstand the ruggedness of live exercises. During live exercises, a medic at the time of injury will obtain Combat Causality Care (CCC) information from a mobile device. The mobile device will allow the medic to see the mechanism of the injury, injury, signs and symptoms, and treatment (MIST), in addition to tactical and vital information. With the information obtained from the mobile device, the medic will be able to leverage the tools that support care of preventable deaths to provide the causality with initial treat. The mobile device will provide the medic with dynamic visual updates of MIST, tactical information, and vital signs real-time. This will provide the medic with real-time injury status information allowing the medic to course correct treatment if necessary. The intention of this topic is to utilize mobile technologies to allow self, buddy, CLS, and medic treatment in live exercises. With technologies that provide dynamic visual updates of MIST, tactical information, and vital signs in real-time the individual providing treatment will be able treat the causality throughout the duration of the exercise, resulting in a more robust training.This topic seeks a high fidelity robust and ruggedized mobile solution for TC3 training. The research and development will focus on both the hardware and the software components. The hardware components should be lightweight, rugged enough to withstand live training, and communicate via Bluetooth or similar technology so that the tools that support care of preventable deaths can transmit the type of treatment to the mobile device. In addition, to increase the fidelity of TC3 simulated training in live exercises the hardware should leverage technologies that provide sensory information to the individual providing care, such as haptics, auditory, and olfactory cues and feedback. The software should succinctly display dynamic visual updates of MIST, tactical information, and vital signs real-time. The real-time information should be based on type of treatment provided by the medic in conjunction with physiological models to represent a persons vitals over time. Physiological models could be derived from software programs such as BiogearsTM and HumModTM (see references) In addition the mobile causality display toolkit should generating real-time data to improve the Commanders Casualty Response System, individual TC3 training, and After Action Review (AAR).Research conducted under this effort should focus on Commanders Casualty Response System, individual TC3 training, and AAR. The final demonstration should show proof-of-concept feasibility for a mobile causality display toolkit that withstands the ruggedness of live training, communicates via Bluetooth to provide treatment updates to the medic via the mobile display, and provides real-time MIST, tactical, and vital information based on physiological models. PHASE I: Identify one or multiple methods for a robust and ruggedized mobile causality toolkit, ensuring that the toolkit components are rugged enough to withstand live training and that the treatment information can be transmitted from the tools to the mobile display. The effort should clearly analyze and define scientific and technical feasibility, as well as commercial merit, of using a mobile causality display toolkit for TC3. The effort should seek innovative and novel ideas for exploration of concepts to provide a rugged and realistic solution that would allow for hands on training. Phase I deliverables should include a proof of principle prototype demonstration or a set of technical drawings in electronic format that would provide a view of all components of the proposed system, Phase II design plans, and exploration of commercialization with potential medical development and manufacturing companies. The offeror shall identify innovative technologies being considered, technical risks of the approach, costs, benefits, plan for development, notional schedule associated with development, and a literature search to support feasibility. PHASE II: From the Phase I design, develop a ruggedized prototype and demonstrate the real-time presence of the mobile causality display toolkit and sensory cues and feedback. The prototype toolkit can be initially demonstrated in an area where Bluetooth signal is strong, knowing that the goal of the prototype is for Bluetooth to work in areas where signal strength is less than ideal. The offeror shall conduct usability studies during development of the system. The offeror shall provide projection of costs to manufacture, maintain and resupply, as well as the equipment lifecycle. The offeror shall conduct a training effectiveness evaluation (TEE) of the final prototype with combat medics. The evaluation shall provide quantitative measures of the effectiveness of the system. Data from the usability studies and the TEE shall be provided, analyzed, and presented in a final report. The offeror shall continue commercialization planning and relationship development with military and civilian end users and begin to execute transition to Phase III transition and commercialization in accordance with the Phase I commercialization plan. PHASE III: Refine and execute the commercialization plan included in the Phase II Proposal. After Phase III development, the final production model of mobile causality display toolkit for TC3 must be ruggedized for shock, dust, sand, and water resistance to enable reliable, uninterrupted operation in combat environments. Service members will wear the mobile display and medics will carry the tools, thus size and weight are important factors. The ultimate goal of the system would be to enable simulated real-time assessment, monitoring, and intervention of causalities during live training. Additionally, the toolkit should generate real time data to improve the Commanders Casualty Response System, individual TC3 training, AAR. Execute proof-of-concept evaluation in a suitable operational environment (e.g. military operations in urban terrain site). REFERENCES: 1: Milham, L. M., Phillips, H. L., Ross, W. A., Townsend, L. N., Riddle, D. L., Smith, K. M., ... & Johnston, J. H. (2016). Squad-level training for Tactical Combat Casualty Care: instructional approach and technology assessment. The Journal of Defense Modeling and Simulation: Applications, Methodology, Technology, 1548512916649075.Link:

Toolkit For Android Free Download

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Compared to the RenderScript Intrinsics, this Toolkit is simpler to use and twice as fast when executing on the CPU. However RenderScript Intrinsics allow more flexibility for the type of allocations supported. This toolkit does not support allocations of floats; most the functions support ByteArrays and Bitmaps. e24fc04721