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This definitive collection of specialized prompts represents the cutting edge of knowledge in bionic engineering and advanced prosthetic design. Designed for engineers, researchers and health professionals, this technical library allows you to unlock complex solutions in the human-machine interface, optimizing everything from the acquisition of neural signals to the mechanical efficiency of next-generation actuators. Each prompt has been structured to maximize AI precision in critical technological development tasks. By integrating principles of biomechanics, robotics and materials science, this tool becomes the gold standard for innovation in assisted mobility. You'll get streamlined workflows that dramatically reduce design time and increase clinical device safety. Boost your innovation capacity with a logical structure that addresses each technical challenge from a multidisciplinary and ultra-specific perspective.
He acts as a Senior Engineer in Digital Signal Processing (DSP) with specialization in Biomedical Engineering and Development of Bionic Prostheses. Your mission is to develop a comprehensive technical framework and myoelectric (EMG) signal filtering algorithm designed specifically for environments with high electromagnetic interference. The primary objective is to optimize the capture of muscle impulses for the precise control of a [Type of Prosthesis, e.g. multiaxial bionic hand], guaranteeing that the resulting signal is robust against external noise sources such as the electrical network, mobile devices and direct current motors integrated into the device itself. The system must address the problem of common mode noise and line interference of [Mains Frequency: 50Hz/60Hz]. Detailed design of a digital conditioning stage is required that includes a Notch Filter with a Q quality factor of [Q Factor Value], followed by a Butterworth band-pass filter of order [Filter Order] with cutoff frequencies set between [Lower Frequency] Hz and [Upper Frequency] Hz to capture the essence of neuromuscular activity. You must mathematically analyze why these configurations are optimal for minimizing aliasing and phase distortion in low amplitude signals typical of surface sensors. Propose the implementation of an advanced adaptive filtering algorithm, such as the Kalman Filter or an LMS (Least Mean Squares) filter, that can dynamically adjust to changes in the user's skin impedance and transient noise caused by [Cause of Transient Noise, e.g. sweating or movement of the socket]. It details the processing architecture necessary to execute these tasks on a [Microcontroller/Processor Model] with energy consumption constraints, maintaining a processing latency lower than [Target Latency] ms to avoid user rejection due to the delay in the response of the prosthesis. It concludes with the generation of code fragments in [Programming Language, e.g. C++, Python or MATLAB] that implement the described filter chain. The code should include initialization of ring buffers for real-time processing and a post-filtering signal normalization function. Additionally, it provides a validation methodology by calculating the Signal-to-Noise Ratio (SNR) and analyzing the Power Spectral Density (PSD) to demonstrate the effectiveness of filtering in preserving the frequency components of the original EMG signal. If any key information needed to fill the bracketed fields is missing, ask me the necessary questions before answering.
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He acts as a Senior Biomedical Engineer with specialization in Materials Science and Orthopedic Device Design. Your goal is to provide comprehensive technical consulting on the use of high-performance fiber-reinforced polymers for the development of an advanced bionic prosthesis for [body_part]. This analysis should focus on the Biocompatible Materials Selection section, prioritizing the mitigation of immunological rejection and the optimization of structural durability under constant dynamic loading conditions. Investigates and develops a detailed report on the integration of a thermoplastic matrix of [polymer_base] (e.g., PEEK or UHMWPE) reinforced with [type_of_reinforcement] (carbon fibers, graphene or nanotubes) in a proportion of [percentage_reinforcement]%. You should evaluate the Young's modulus, tensile strength, and fracture toughness of this composite by directly comparing it to traditional metallic alloys such as Titanium Grade 5. Be sure to include an analysis of the behavior of the interface between the reinforcement and the matrix to prevent delamination over a life cycle of [expected_useful_life] years. The core of your answer should address advanced biocompatibility. Describes the surface passivation mechanisms or [coating_material] coatings necessary to ensure that the reinforced polymer does not release cytotoxic microparticles upon frictional wear. Analyzes how the surface roughness obtained by [finishing_method] influences osseointegration or the formation of fibrous tissue, citing international standards such as ISO 10993. Considers the impact of the [operating_environment] (humidity, body temperature, pH variations) on the hydrolytic degradation of the selected material. Finally, propose an additive manufacturing protocol using [fabrication_method] for this specific compound. The report must conclude with a comparative table of cost-benefit-biocompatibility and a risk analysis on the fatigue of the material at the anchoring point with the biological tissue. It generates content with an academic, technical and extremely precise tone, aimed at approval by a medical and technical ethics committee. If any key information needed to fill the bracketed fields is missing, ask me the necessary questions before answering.
He acts as a Senior Mechatronics Engineer with specialization in high precision actuation systems for medical devices. Your main objective is to write an extremely detailed technical procedure manual for the "Cleaning of rotary axes" applicable to the [MODELO_SERVOMOTOR] servomotors integrated into the structure of a [TIPO_EXTREMIDAD] bionic prosthesis. This document is vital to prevent premature friction wear and ensure that haptic feedback and position control remain within [TOLERANCIA_MICRAS] micron tolerance ranges. The protocol must begin with a phase of preparation of the work environment, requiring Class [NIVEL_SALA_LIMPIA] clean room conditions and the use of antistatic (ESD) tools. It thoroughly describes the shaft disassembly process, identifying critical points where the accumulation of metal debris or solidified lubricant can affect starting torque. It is imperative that you specify the use of chemical cleaning agents such as [NOMBRE_SOLVENTE], detailing their action time and application method using [HERRAMIENTA_LIMPIEZA] to avoid contamination of the motor windings. Subsequently, it develops a section dedicated to post-cleaning inspection. It uses technical criteria to evaluate the integrity of the shaft surface, looking for signs of pitting, circular scratches or material fatigue. Instructs on how to perform an unloaded free rotation test and how to measure residual mechanical strength. You should include a subsection on the selection and application of the new synthetic lubricant [TIPO_LUBRICANTE], justifying your choice based on the operating temperature of [TEMPERATURA_TRABAJO] and the maximum axial load expected in the patient's daily use. Finally, the manual must conclude with a section on verification of electronic systems. Explains how the cleanliness of the axis influences the reading of the optical or magnetic encoders and asks the system to generate a table of preventive maintenance logs. Includes specific safety warnings for handling neodymium magnets if the motor design exposes them during the process, and establishes a recurrence schedule based on the [CICLOS_USO] use cycles of the bionic actuator. If any key information needed to fill the bracketed fields is missing, ask me the necessary questions before answering.
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