SDR Implementation by Organization - Paper Example

7. Environment

There are several legal, social, ethical and sustainable and other related concerns that are related to our project of making an SDR. Having noted the above, we have to consider the factors the environment that is related to SDR implementation, hence this chapter will be exploring the factors surrounding SDR environment.

7.1 Legal

First, SDR is competing against normal radio. Hence, in creating this product, it is important to evaluate the nature of the market hence come up with an appropriate product engineering mechanism. However, the major concern is the software copyright issues. In this case, other companies are competing against our product which makes it difficult to engage directly. Hence, we need to evaluate our products against those of our competitors. In the evaluation, we are going to be comparing what our competitors are offering while contrasting with ours. Hence, we are going to major our case on the innovation argument, clearly distancing from other projects involved. The goal is to ensure that our products are legitimized by hybridizing a number of known technologies to look new and unique for the market. As such, it will be easier to render the project in the market than to keep it vacant and open.

7.2 Social

There are social factors that surround the implementation of technology. Kapitsa et al. argue that there are justifying social factors that oversee the implementation of the technology, primarily those that involve the social, and legal parameters. In this case, the technology creates complex social procedures that surround the implementation of the technology. The project majors its case on the need to facility the positive change that SDR brings to the society. As such, it will be possible to approach the different technology barriers and different organizational incompatibilities depend naturally on the technical skills that surround the market. Panda et al. (2017) use a LabVIEW to conduct the procedure of ground receiver system using to explain the social development of the product. The ground receiver system depends on the general processing units for the high-speed PCI extension as well as instrumentation and expresses cards. Given the communication systems utilizes modulation and demodulation systems, SDR easily achieves standard frequency, a noise figure, and measure sensitivity. Such changes remain major concerns to the different communities surrounding making food and meeting the appropriate consumer needs (International Conference on Software Reuse, Kapitsaki, and Almeida, 2016). Increased usage of SDR means the general reliance on Smartphone devices, could there be other challenges. Increased use of SDR means the consumption of the radio products, black metal music not limited. The goal here is how the diversity influences the society up to what extent.

7.3 Ethical

There are ethical factors involved in the adoption of technology. The ethical factors involve the possibilities that lead to the obscurity for the fact that technology relates to the destructive potential win of technology. In this case, the central marvelous benefits of technology surround the potential risk of generating and reusing technology. The easy access to technology depends and advances for wireless telecommunication. Approaches the subject of sustainability by introducing abstract debates on DDRI, RDRAM and DDRII for the overall basic innovations for the differences will be discussed that are different areas topics for the modules, architecture, and interfaces. Clearly, the approach being applied here is that innovations and differences being applied to create interfaces and architecture as oriented by the different modules. Reza et al. (2011) apply the logic of universal neutral network demodulator for SDR. The data processing mechanism used in SDR are configured to detect data bits that are perfectly created through a feedback mechanism while creating a proper noise limiter. Such ethical issues frequently arise for the practice engineering and science courses. In fact, the ethical issues keep pace with the rapid changes. The research and professional practice involve the ability to apply professional and ethical codes while reflecting on the changes in the industry itself. The SDR should be completely produced and effective in nature. In this case, there are ethical orientations that have emerged in the society. Orientation, for instance, cultural relativism, eroticism, pragmatics, and intuitionism are a popular extension for the unprecedented nature that results to the advances in technology for the particular engineering being used.

7.4 Sustainability

Sustainability is naturally related to the people, nature, and societies. In this case, the sustainable factors of building through the practice requirements of people and society on the optimal way while during the life cycle of the building facility. In SDR, sustainability is generally related to the life cycle principle with the application for the methodology of design manufacture, maintenance, and construction and building projects. Khan (2014, p. 108) claim that SDR sustainability is generally related to the durability of the design, whether the software is affected by the bugs, and whether the hardware is prone to the durability. Machado-Fernandez (2015) explores SDR provision includes the hardware schemes for application fields. The performance is related to the cost consideration which surrounds the nature of technologies that is related to the different software development. Blech et al. (2010) argue the ultra-wideband for software defined radio that is being developed through the impulse radio for trans-receiver while employing the different bandpass sampling and conversion frequency. The journal approaches the subject of sustainability by exploring the usefulness of technology Field Programmable Gate Array (FPGA). The reconfigurable design process creates an extensive performance analysis while creating the right quadrature phase for shifting to the appropriate modulation scheme investigation through different amplifiers for the narrowband. The design process includes the proper commencement of the dimensions and design calculation. The control of moisture and thermal, therefore, an important tool that surrounds natural and non-renewable resources involved in reducing the environment impact created at different instances (Kaabouch and Hu, 2012, p. 143). For SDR, the energy consumption depends naturally on the properly controlled heating and ventilating recover, as well as the insulation and the, envelop that is important. Other factors that are closely considered durability and flexibility that relates to the functional changes for the spaces and service systems for the important lifecycle of products.

8. Conclusions

As established, Software Defined Radio (SDR) creates a perfect computational approach that distances from the analog systems which further involves embracing a complex and properly defined machinery for the analog systems. As stated, there are possible tests combinations that help in configuring SDR mechanism. The errors in SDR design have an effect on faulty radio. The wideband SDR could conceivably be a combination of the FEC block lengths and time constant of adaptive loops that introduce various levels of complexity. Testing an SDR depends naturally on the problems that surround the switching various specific waveforms to each other. The RD involves recreating a perfect system design while adopting a methodology that justifies the procedure of the SDR.

As stated, SDR improves the signaling process while increasing the possible transceiver linearity that is vital for the multiband through the transceiver

As examined, the potential investment mechanism depends naturally on the radical advances in the frequency components.

As noted, the SDR upgrade creates a reliable software communication architecture depends on the convenient and responsive applicable technologies.

Hence, a properly well-implemented SDR depends naturally in achieving various strategic objectives. However, the SDR design equally faces significant challenges as well as arguments that continuously challenge, that have been tackled in this project.

8.1 Recommendations

8.1.1 Project size.

In making the perfect SDR plan, it is important to have a client-server architecture for the defined customer and users that are in place for the existing software architecture. This will help iron out the possible challenges that are identified in the project management mechanism.

8.1.2 Customer or product owner must be agile

It is important to consider the customer or product development while prioritizing on the most important features for the SDR development. In this case, the customer will come first, based on the legal, social and sustainable factors. The ability to redefine the requirements, recreate a procedure for entitlement as well prioritizing on the requirements for project development depends significantly on the choices for product development.

8.1.2 Your organization must be agile

The SDR manufacturing firm should be agile and responsive to the different software development. In fact, the goal should reflect on the need for the different software development mechanism. As well, the goal involves adopting a perfect ongoing work while creating a procedure for software development.

8.1.3 Your team might not be ready

It is important to encourage the project team to create mature efforts that recreate the appropriate approach for project development. The team is being advised to go agile and lead accordingly. The agility approaches require the appropriate mental shift that relates to the product development mechanism. The overall goal of the team reflects on the mature way to understand and recreate a project implementation strategy.

References

Blech, M., Ott, A., Neumeier, P., Moller, M., & Eibert, T. (2010). A reconfigurable software defined Ultra-wideband impulse radio transceiver. Advances In Radio Science, 8, 67-73. http://dx.doi.org/10.5194/ars-8-67-2010Cwalina, K., Rajchowski, P., & Sadowski, J. (2016). Wideband Radio Direction Finder Implemented in Software Defined Radio Technology. Applied Mechanics and Materials, 817, 348-355. http://dx.doi.org/10.4028/www.scientific.net/amm.817.348Gomez, I., Marojevic, V., & Gelonch, A. (2012). Resource Management for Software-Defined Radio Clouds. IEEE Micro, 32(1), 44-53. http://dx.doi.org/10.1109/mm.2011.81International Conference on Software Reuse, In Kapitsaki, G. M., & In Almeida, E. (2016). Software reuse: Bridging with social-awareness : 15th International Conference, ICSR 2016, Limassol, Cyprus, June 5-7, 2016, Proceedings. Switzerland : Springer, 2016.

Klehn, B., & Brox, M. (2003). A Comparison of current SDRAM types: SDR, DDR, and RDRAM. Advances In Radio Science, 1, 265-271. http://dx.doi.org/10.5194/ars-1-265-2003Machado-Fernandez, J. (2014). Software Defined Radio: Basic Principles and Applications. REVISTA FACULTAD DE INGENIERIA, 24(38), 79. http://dx.doi.org/10.19053/01211129.3160Magnuski, M., Surma, M., & Wojcik, D. (2014). Broadband Input Block of Radio Receiver for Software-Defined Radio Devices. International Journal Of Electronics And Telecommunications, 60(3). http://dx.doi.org/10.2478/eletel-2014-0029Panda, A., Mishra, D., & Ratha, H. (2017). A Software Defined Radio based UHF Digital Ground Receiver System for Flying Object using LabVIEW. Defence Science Journal, 67(3), 291. http://dx.doi.org/10.14429/dsj.67.10365Reza Amini, M., Balarastaghi, E., & Branch, B. (2011). Universal Neural Network Demodulator for Software Defined Radio. International Journal Of Engineering And Technology, 3(3), 263-268. http://dx.doi.org/10.7763/ijet.2011.v3.235Kaabouch, N., & Hu, W. C. (2012)...