Quality Assembly: Designing to offsite fabrication for medium density living in New Zealand

<p>This research portfolio looks at how consciously activating prefabrication into the design process early, and subsequently designing to the onsite assembly stage by using three key design principles, can contribute to a responsive design that embodies quality medium density living in New Zealand. Prefabrication is at the forefront of the New Zealand Government’s conversation about its residential construction industry. The potential attributes of this efficient construction method of fast on-site installation time, reduced cost, improved construction safety, and improved construction quality, have the potential to positively impact the issues that our housing industry faces. However, the intrinsic limitations that come with prefabrication being based on the ideals of efficiency, carry the risk (as seen throughout its history) of compromising the design quality. With the motivation to integrate this construction process into New Zealand’s commonplace residential construction industry based on its positive attributes, it is essential to address its relationship to the designed outcome, and consequently the design process. Ryan E. Smith of Washington State University in Prefab Architecture expresses that prefabrication is a construction process not a product so a poor design results from a poor designer. He specifies that for a prefabrication project to achieve quality construction and aesthetics the design process must be directed to “quality assembly”. This idea endorses the integration of this chosen construction process in accordance with the design intent and guide the design through various scales to the detailing of assembly. For this integration of ‘quality assembly’ into the design process three principles have been interpreted from founding literature as being key drivers: standardisation, repetition, and personalisation. Standardisation is the act of simplifications to efficiently design. Based on chosen factors measurements are controlled allowing pieces, elements, and/or units to relate to one another cleanly. Repetition is the act of reducing variances within the construction, maximising the efficiency of prefabrication. Traditionally this can improve quality. Personalisation is the principle that relates the desirability of the outcome with the necessity appropriately suiting its site and occupancy. This research is positioned within New Zealand’s residential climate, which is seeing a growing demand for medium density living. The defined programme accommodates two key demographics within this density of first-home buyers and homeowners downsizing. The focus is to design a system that assists quality living – giving an alternative archetype – for New Zealand’s evolving climate. Key findings from this research support the design intent of ‘designing to assembly’, whereby the construction process and the outcome are integral to one another. By focussing collectively on standardisation, repetition, and personalisation, a responsive design that is suitable to various sites and occupancies can be realised. The challenge lies within balancing flexibility with restriction efficiently.</p>

Quality Assembly: Designing to offsite fabrication for medium density living in New Zealand

<p>This research portfolio looks at how consciously activating prefabrication into the design process early, and subsequently designing to the onsite assembly stage by using three key design principles, can contribute to a responsive design that embodies quality medium density living in New Zealand. Prefabrication is at the forefront of the New Zealand Government’s conversation about its residential construction industry. The potential attributes of this efficient construction method of fast on-site installation time, reduced cost, improved construction safety, and improved construction quality, have the potential to positively impact the issues that our housing industry faces. However, the intrinsic limitations that come with prefabrication being based on the ideals of efficiency, carry the risk (as seen throughout its history) of compromising the design quality. With the motivation to integrate this construction process into New Zealand’s commonplace residential construction industry based on its positive attributes, it is essential to address its relationship to the designed outcome, and consequently the design process. Ryan E. Smith of Washington State University in Prefab Architecture expresses that prefabrication is a construction process not a product so a poor design results from a poor designer. He specifies that for a prefabrication project to achieve quality construction and aesthetics the design process must be directed to “quality assembly”. This idea endorses the integration of this chosen construction process in accordance with the design intent and guide the design through various scales to the detailing of assembly. For this integration of ‘quality assembly’ into the design process three principles have been interpreted from founding literature as being key drivers: standardisation, repetition, and personalisation. Standardisation is the act of simplifications to efficiently design. Based on chosen factors measurements are controlled allowing pieces, elements, and/or units to relate to one another cleanly. Repetition is the act of reducing variances within the construction, maximising the efficiency of prefabrication. Traditionally this can improve quality. Personalisation is the principle that relates the desirability of the outcome with the necessity appropriately suiting its site and occupancy. This research is positioned within New Zealand’s residential climate, which is seeing a growing demand for medium density living. The defined programme accommodates two key demographics within this density of first-home buyers and homeowners downsizing. The focus is to design a system that assists quality living – giving an alternative archetype – for New Zealand’s evolving climate. Key findings from this research support the design intent of ‘designing to assembly’, whereby the construction process and the outcome are integral to one another. By focussing collectively on standardisation, repetition, and personalisation, a responsive design that is suitable to various sites and occupancies can be realised. The challenge lies within balancing flexibility with restriction efficiently.</p>

Rootstock and Nutrient Imbalance Leads to ‘‘Green Spot’’ Development in ‘WA 38’ Apples

‘WA 38’ is a new apple (Malus domestica Borkh.) cultivar, released by Washington State University (WSU) in 2017. An unknown disorder, ‘‘green spot’’ (GS), dark green halos in the epidermis, with necrotic, corky, and oxidated cortical tissue underneath the damaged epidermis, leads to unmarketable fruit and has become a threat to the adoption and profitability of ‘WA 38’, with young and mature orchards exhibiting up to 60% incidence in 2020. Given the apparent susceptibility of ‘WA 38’ to GS, this research investigated GS relation with nutrient levels in fruit. Research was carried out in 2018 and 2019 in a ‘WA 38’ apple block planted in 2013, on ‘Geneva 41’ (‘G.41’) and ‘M.9-Nic 29’ (‘M.9’) rootstocks. In both years, fruit number per tree, fruit weight, and fruit diameter were evaluated in 18 trees per treatment, from both rootstocks. From each tree, fruit were classified for presence or absence of GS, and subsequently analyzed for nutrient concentration in the peel and in the flesh, nutrient extraction, and total nutrient content, on an individual apple basis. Apples with GS had higher nitrogen (N) and magnesium (Mg) levels in the peel, regardless of year and rootstock. Apples grown on ‘G.41’ rootstock exhibited higher GS incidence and reduced crop load in both years; reduced size and fruit diameter were exhibited only in 2018. Fruit on ‘G.41’ had higher N, potassium (K), and Mg in the flesh and higher N and Mg in the peel, with lower levels of calcium (Ca) in the flesh and peel; however, only in 2018, with no differences in 2019. GS in ‘WA 38’ apples appears to be another Ca-related disorder in which excessive vigor, rootstock, and N and Mg excess are predisposing factors for its development.

Trends in Fruit Quality Improvement From 15 Years of Selection in the Apple Breeding Program of Washington State University

Washington State University's apple breeding program (WABP) was initiated in 1994 to select new apple cultivars with improved eating quality, appearance, and storability that are suitable for production in the main growing regions of the state. Fruit quality is phenotyped using various instrumental measures, such as penetrometers (texture), titrator (acidity), and refractometer (soluble solids concentration; SSC), as well as sensory assessment. The selection regime of WABP occurs in three sequential phases: phase one (P1)—single, unreplicated seedlings at one site, phase two (P2)—replicated selections at three geographically diverse sites, and phase three (P3)—highly replicated elite selections at one to two grower sites. Most of the data collection of WABP occurs in P2. Knowledge of trends/changes associated with advancing selections is essential for understanding the selection criteria and progress of WABP throughout the changing compositions of advancing and culling selections. For each post-harvest trait, P2 data from harvest years 2005 to 2019 were split across sites, and between selections and reference cultivars (e.g., Cripps Pink, Gala, and Honeycrisp). Means of instrumental crispness (Cn) and inner cortex firmness for the advancing selections increased gradually over this period and were significantly higher than those for cultivars. Means of outer cortex firmness measurements were stable for selections but significantly higher than those for cultivars. The average fruit acidity of selections increased marginally over this period and was higher than that of the cultivars. Meanwhile, the average fruit SSCs of selections and cultivars were statistically indistinguishable. These 15-year trends indicate that WABP has been selecting apples with improved eating quality and storability through increased crispness and inner cortex firmness, respectively.

Binary Sensors-Based Privacy-Preserved Activity Recognition of Elderly Living Alone Using an RNN

The recent growth of the elderly population has led to the requirement for constant home monitoring as solitary living becomes popular. This protects older people who live alone from unwanted instances such as falling or deterioration caused by some diseases. However, although wearable devices and camera-based systems can provide relatively precise information about human motion, they invade the privacy of the elderly. One way to detect the abnormal behavior of elderly residents under the condition of maintaining privacy is to equip the resident’s house with an Internet of Things system based on a non-invasive binary motion sensor array. We propose to concatenate external features (previous activity and begin time-stamp) along with extracted features with a bi-directional long short-term memory (Bi-LSTM) neural network to recognize the activities of daily living with a higher accuracy. The concatenated features are classified by a fully connected neural network (FCNN). The proposed model was evaluated on open dataset from the Center for Advanced Studies in Adaptive Systems (CASAS) at Washington State University. The experimental results show that the proposed method outperformed state-of-the-art models with a margin of more than 6.25% of the F1 score on the same dataset.

WSU ROAR and ROAR Online! Program Description and COVID-19 Response

Washington State University, Responsibility Opportunity Advocacy and Respect (WSU ROAR) is an inclusive 2-year residential postsecondary education program for students with intellectual and developmental disabilities. WSU ROAR is a recognized comprehensive transition program located in rural eastern Washington. Within the program, there are four pillars: WSU ROAR workshops, Washington State University audit courses, employment experiences, and independent living. Individualized instruction guides the WSU ROAR workshops to allow students to develop their independence. Students also participate in audit courses in inclusive settings on campus to gain skills to help with future employment opportunities. Peer Allies, who are students traditionally enrolled at college, provide meaningful social and academic relationships by partnering with the students in WSU ROAR. This program description discusses the development of the postsecondary education program and its adaptation to meet its goals while addressing the challenges of being a rural university in eastern Washington. This program description also describes how the WSU ROAR program adapted to a remote learning platform during the COVID-19 pandemic.

Using the 4-H Essential Elements to Evaluate Teen Programming

National and state trends indicate participation in 4-H programming declines throughout adolescence. Past research suggests factors that may influence recruitment and retention of teens into youth development programming. Washington State University undertook an evaluation to understand the needs and desires of teens in the 4-H program and make recommendations for improvements to recruitment and retention of teens in 4-H. The study sample was made up of 93 young people aged 12 to 19 years who participated in the online survey. Results included youth demographics, participation styles, communication preferences, youth outcomes, and feedback about program benefits and opportunities for growth. The results of this study are reviewed and framed within the 4-H Essential Elements. Recommendations are made to leverage youth voice and encourage innovation in 4-H teen programming.

Quinoa in Ecuador: Recent Advances under Global Expansion

Quinoa is a highly diverse crop domesticated in the Andean region of South America with broad adaptation to a wide range of marginal environments. Quinoa has garnered interest worldwide due to its nutritional and health benefits. Over the last decade, quinoa production has expanded outside of the Andean region, prompting multiple studies investigating the potential for quinoa cultivation in novel environments. Currently, quinoa is grown in countries spanning five continents, including North America, Europe, Asia, Africa, and Oceania. Here, we update the advances of quinoa research in Ecuador across different topics, including (a) current quinoa production situation with a focus on breeding progress, (b) traditional seed production, and (c) the impact of the work of the nongovernment organization “European Committee for Training and Agriculture” with quinoa farmers in Chimborazo province. Additionally, we discuss genetic diversity, primary pests and diseases, actions for adapting quinoa to tropical areas, and recent innovations in quinoa processing in Ecuador. Finally, we report a case study describing a participatory breeding project between Washington State University and the Association of Andean Seed and Nutritional Food Producers Mushuk Yuyay in the province of Cañar.

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