Consider the “Statement on the Integration of Faith and Work,” and the tenets of servant leadership, conscious capitalism, and the sustainable development goals described in the “Measuring Progress Towards the Sustainable Development Goals” study material. Select a sustainable development goal that you would like to promote. Review the “How to Build a Mobile App Requirements Document” study material.
Imagine that your company is partnering with the United Nations to plan and design a mobile app as part of an initiative to fundraise and increase awareness about your selected sustainable development goal. Create a 10-slide PowerPoint presentation that outlines the plan and design specifics of your mobile app and explains how the app can be used to drive business results and create a competitive advantage for the organization in increasing awareness and fundraising to meet goal-relevant needs. Include speaker notes to provide details about the content of each slide. Throughout the presentation, include discussion of the importance of business being a force for good to improve society and help communities prosper and how the tenets of servant leadership and conscious capitalism can be applied to the project to ensure this is appropriate. The presentation should include the following.
- Business requirements, mobile app objectives, and product vision statement.
- Target audience and user journey.
- List of features.
- Monetization model.
- Product and technical specification.
- Platforms for which the app is being developed.
- Maintenance and upgrade requirements.
- Dependencies, assumptions, constraints, and submission.
- Explain how the app could create a competitive advantage for the organization.
Sample Solution
with various focuses and diverse proportion of natural stage: watery stage. Albeit, all formulae produce nanoparticles, plan factors essentially influence the size of arranged polymeric nanoparticles. 3.1. Impact of polymer fixation and polymer type on molecule size of plain PNPs : Molecule size of Eudragit S100 and HPMC Phthalate HP55 nanoparticles was straightforwardly relative to polymer focus (Eudragit S100 and HPMC Phthalate HP55 fixation individually) as the particles size expanded with expanding polymer focus [211, 212] and this might be because of expanding the grouping of broke down polymer brought about expanding natural stage consistency and lessening the proficiency of blending which caused arrangement of the greater emulsion beads [213] and this can be additionally ascribed to that higher thickness that is unsurprising to build polymer â polymer and polymer-dissolvable communications [147, 214]. At the point when polymer focus on account of Eudragit S100 and HPMC Phthalate HP55 was expanded from 0.2 gm% to 0.8 gm% with Tween 80 convergence of 0.5% w/v and stage proportion of (1:2), molecule size was expanded from 390±9.4634 to 714±2.0548 and from 434±3.0912 to 863±0.9428 nm separately. A similar impact of polymer focus on molecule size was the equivalent either on account of expanding Tween 80 fixation and/or expanding the stage proportion as appeared in the tables (4, 6 and 8) and figures (3, 5 and 7). At the point when polymer fixation on account of Eudragit S100 and HPMC Phthalate HP55 was expanded from 0.2 gm% to 0.8 gm% with Poloxamer 407 grouping of 0.5% w/v and stage proportion of (1:2), molecule size was expanded from 404±8.6538 to 747±1.6997 and from 598±1.633 to 905±4.0277 nm separately. A similar impact of polymer fixation on molecule size was the equivalent either on account of expanding Poloxamer 407 focus and/or expanding the stage proportion as appeared in the tables (5, 7 and 9) and figures (4, 6 and 8). These outcomes were found to concur with the aftereffects of both Galindo-Rodriguez et al., 20>
with various focuses and diverse proportion of natural stage: watery stage. Albeit, all formulae produce nanoparticles, plan factors essentially influence the size of arranged polymeric nanoparticles. 3.1. Impact of polymer fixation and polymer type on molecule size of plain PNPs : Molecule size of Eudragit S100 and HPMC Phthalate HP55 nanoparticles was straightforwardly relative to polymer focus (Eudragit S100 and HPMC Phthalate HP55 fixation individually) as the particles size expanded with expanding polymer focus [211, 212] and this might be because of expanding the grouping of broke down polymer brought about expanding natural stage consistency and lessening the proficiency of blending which caused arrangement of the greater emulsion beads [213] and this can be additionally ascribed to that higher thickness that is unsurprising to build polymer â polymer and polymer-dissolvable communications [147, 214]. At the point when polymer focus on account of Eudragit S100 and HPMC Phthalate HP55 was expanded from 0.2 gm% to 0.8 gm% with Tween 80 convergence of 0.5% w/v and stage proportion of (1:2), molecule size was expanded from 390±9.4634 to 714±2.0548 and from 434±3.0912 to 863±0.9428 nm separately. A similar impact of polymer focus on molecule size was the equivalent either on account of expanding Tween 80 fixation and/or expanding the stage proportion as appeared in the tables (4, 6 and 8) and figures (3, 5 and 7). At the point when polymer fixation on account of Eudragit S100 and HPMC Phthalate HP55 was expanded from 0.2 gm% to 0.8 gm% with Poloxamer 407 grouping of 0.5% w/v and stage proportion of (1:2), molecule size was expanded from 404±8.6538 to 747±1.6997 and from 598±1.633 to 905±4.0277 nm separately. A similar impact of polymer fixation on molecule size was the equivalent either on account of expanding Poloxamer 407 focus and/or expanding the stage proportion as appeared in the tables (5, 7 and 9) and figures (4, 6 and 8). These outcomes were found to concur with the aftereffects of both Galindo-Rodriguez et al., 20>
