I need help developing the system specification (A-spec) for a network of wireless biosensors used for point of care diagnostics.

The specification needs to be written in a formal structure, showing traceability to the requirements, covering system definition, required quantitative characteristics, support requirements, and any special requirements such as safety and human interfaces. It should also include (as appropriate) any concerns the designer may need to take into account, such as incomplete analysis, unstable requirements, business or technology factors that went unaddressed, and areas of design flexibility within the requirements envelope. As appropriate, special instructions to the system designers/developers. The system specification might include requirements metrics. At a minimum, the report shall include:

1. # of initial requirements (from Requirements Analysis Report)
2. # of final requirements (from A-Spec/System Spec)
3. #/% of qualitative requirements
4. #/% of quantitative requirements

This is a wireless biosensor. Used to detect certain biomarkers for diagnostics. Must have emergency alert sent to dr and family member. Battery as a secondary power source in the event of a failure. Energy harvesting is the main source of power. Must be wearable.

. Battery . Pass . Charge in 6 hours Maintain charge when not used . 24 hours of operation time . Fail Takes 10+ hours to charge . Loses voltage when not used . Operation time less than 24 hours . Energy Harvesting Capability . Pass Continuously harvests energy . Fail . Does not continuously harvest energy. Communication . Pass . 24 hours of continuous communication to network in a single day . Fail . Less than 24 hours of continuous communication to network in a single day . Connection loss . Connection drops . User Interface . Pass . Ease of use . Fail . Difficult navigation of interface . Sensor . Pass . Passes shock and vibration resistance . Fail . Significant degradation during stress testSensor Communication Processing Decision support User interface gubsystem: subsystem: subsystem: subsystem: subsystem: .Fault detection . Secure data . Modifiable * Integration of . Interface that is and self- transfer using algorithms to medical simple to use and calibration. authentication accommodate knowledge for mtuitive for a and encryption. STOLEA precise range of * Power control to biomarkers and interpretations stakeholders. enable longer * Protocols with SemSOIs. operation. low power . Alerts and * Support for consumption to . Pattern notifications that multiple extend battery recognition and are languages to life. anomaly customizable. mcreage detection using accessibility machine learning-Key Performance Definition Traceability Quantifiable Parameter The sensor must be Aligns with the Limit the biosensor Miniaturized miniaturized ability of continuous chip size to enhancing patient wearability and 8*10.2mm . comfort comfort The sensor must Aligns with real-time Utilize a lithium- Low Power consume low power continuous baged battery to Consumption which extends the monitoring maximize battery battery life. lifespan. The sensor must have Aligns with providing Use a data wireless a network of transmission rate of Wireless communication biosensors for point- 250 kbpe or faster to Communication capability to achieve of-care diagnostics. ensure faster data real-time data transmission to the transmission. doctor. The sensor must be Aligns with the Use nonmvasive wearable by the patient being able to electrochemical Wearable patient to achieve have continuous sensors to ensure comfort and ease of monitors with maximum comfort mind comfort and ease of for the patient. mind The sensor must have Aligns with providing a networking health insights to Support up to 15 Networking capability to monitor patient trends biosensors per user accommodate for in assistance to and demonstrate numerous biogensors advancing the compatibility on the same network. biogensor healthcare