Body Meets Space. Space Becomes Dress.

Forming. Shifting. Shaping. The envelope of one’s physiological body extends outwards in multiple shells, layer by layer. The versions of this envelope exist in the interstitial moment between clothing and architecture; ever forming and being formed, they shift and shape the circulation and happenings of the body on one side and the world on the other. The study of garments lends architecture recognition of various visible and invisible forces that create space and envelope. When space becomes dress, body specificity and movement is emphasized, and the geometries of the physiological body and what it means to experience space as an individual becomes primary, achieving a qualitative, sensory experience extending from the powers of kinaesthetic sense. Oscillating between scales and acts of making, model experimentation invents new ways to conceive and create architecture — a soft architecture finds itself operating here: on the liminal edge of body, envelope, and space

Body Meets Space. Space Becomes Dress.

Forming. Shifting. Shaping. The envelope of one’s physiological body extends outwards in multiple shells, layer by layer. The versions of this envelope exist in the interstitial moment between clothing and architecture; ever forming and being formed, they shift and shape the circulation and happenings of the body on one side and the world on the other. The study of garments lends architecture recognition of various visible and invisible forces that create space and envelope. When space becomes dress, body specificity and movement is emphasized, and the geometries of the physiological body and what it means to experience space as an individual becomes primary, achieving a qualitative, sensory experience extending from the powers of kinaesthetic sense. Oscillating between scales and acts of making, model experimentation invents new ways to conceive and create architecture — a soft architecture finds itself operating here: on the liminal edge of body, envelope, and space

Generation of Model Analytical Intelligence of Service-Oriented Systems for Quality Management of Their Operation

The article describes the main demand reasons for soft architecture of service-oriented systems. There are shown common analytical studies results of service-oriented systems. We consider a promising approach how to manage their quality. We see the detailed ideas about the purpose of the model-analytical intelligence of service-oriented systems. The paper shows us the extended formal procedures for constructing object-oriented models of service-oriented systems with the intelligent quality control. The author proposes a method for generating model-analytical intelligence of service-oriented systems with a controlled quality of their functioning.

Choreographed Soft Morphologies: exploring new ways of ideating soft architecture through material elasticity

This research aims to contribute to the current field of architectural design by offering evidence of how a collaborative and embodied approach to soft architecture can inform a new physical-digital design process. Current design technologies (e.g. sensors, 3D scanners, procedural modelling software), together with the use of the body as a source for designing a space, offer new methods and tools for designing architecture (Hirschberg, Sayegh, Frühwirth and Zedlacher 2006). However, the potential for experiencing and digitally capturing a soft and elastic material interaction through the body as a dynamic system capable of informing soft architectural design has not yet been widely explored. By using the felt experience as a tool for design, we allow the material to express its qualities when activated by the body, revealing its form instead of it being imposed from outside (DeLanda 2015). Taking an embodied approach used in interaction design and fashion design (Loke and Robertson 2011; Wilde, Vallgårda, and Tomico 2017), this research proposes a hybrid method to explore a textile-body ontology as an entity that has the potential to design a space, along with the use of motion capture technology in an effort to re-connect the experiential (the body) with the architecture (the space). Through a custom-made interface, made of soft and hard materials, we explored the dynamic and spatial qualities of material elasticity through choreographed body movements. The interface acts as a deformable space that can be shaped by the body, producing a collection of form expressions, ranging from subtle surface modifications to more prominent deformations. Such form-giving processes were captured in real time by three Kinect sensors, offering a distinct digital raw material that can be conveniently manipulated and translated into architectural simulations, validating the method as a new way to inform soft architectural design processes. The findings showed that: 1) the direct experience of collaboratively interacting with a soft and elastic interface allows the identification of the dynamic qualities of the material in relation to oneself and others, facilitating an immediate spatial meaning-making process; 2) exploring the design of a soft and elastic space through choreography and motion capture technology contributes to the creation of augmented relational scales across physical and digital realms, proposing a new hybrid design method; 3) the soft and elastic interface becomes a new entity when shaped by the body (textile-body ontology) giving the opportunity for a variety of formal expressions and offering a source of digital raw material for architectural design.

Cavity Beam Position Monitor Test System Based on Virtual Instrument

Based on the virtual instrument technology, a dedicated test system has been developed for cavity beam position monitor (CBPM). The system consists of commercial nanopositioning stage and its controller, the analog output DAQ card based on PXI and network analyzer. In the LABVIEW environment, software which implemented function of instrument control and data acquisition based on virtual instrument soft architecture (VISA) has been developed. Experimental results illustrated that the test system achieved positioning precision of sub micron which meets requirement of test of CBPM. Also it could serve CBPM signal processing system.