The perceived position of a moving object is reset by temporal, not spatial limits

When the internal texture of a Gabor patch drifts orthogonally to its physical path, its perceived motion deviates dramatically from its physical path. The local position shifts accumulate to such an extent that a 45 deg oblique physical path appears to be vertical. However, at some point, a limit is reached and the path resets back to its veridical location, whereupon a new accumulation starts, making the new perceived path segment appear parallel to the pre-reset segment, but offset horizontally from it. Here, we tested whether spontaneous resets of this motion-induced position shift depend on the time or the distance over which position errors accrue, or both. We introduced a temporal gap in the middle of the path that forced the illusory path to reset back to its veridical physical position. This gap-triggered reset allowed us to measure the magnitude of the illusory offset up to that point. We found that perceived offset was less than expected for the angle of illusory drift, indicating that spontaneous resets had occurred prior to the gap-induced reset. The position offset decreased when the pre-gap duration increased but approximately doubled when the path length doubled. This pattern of perceived offsets is best accounted for by spontaneous resets that occur randomly over time at a constant rate, independently of the distance traveled. Our results suggest a temporal, not spatial, limit for the accumulation of position errors that underlies this illusion.

Genetic Dissection of the Powdery Mildew Resistance in Wheat Breeding Line LS5082 Using BSR-Seq

Wheat powdery mildew is a destructive disease seriously threatening yield and quality. Comprehensive dissection of new resistance-related loci/genes is necessary to control this disease. LS5082 is a Chinese wheat breeding line with resistance to powdery mildew. Genetic analysis indicated that a single dominant gene, tentatively designated PmLS5082, conferred seedling resistance to different Bgt isolates. Bulked segregant RNA-seq (BSR-seq) was carried out to map the R gene PmLS5082 and profile differentially expressed genes associated with PmLS5082. PmLS5082 was mapped to chromosome arm 2BL and flanked by the markers WGGBH612-5 and YTU19-005 with genetic distances of 0.3 and 0.4 cM, respectively. The physical position was subsequently locked into the interval of 710.3-711.0 Mb. PmLS5082 differs from the catalogued Pm genes on chromosome arm 2BL in its resistant spectrum, physical position and origin, suggesting it is most likely a new Pm gene. Through COG and KEGG analysis, differentially expressed genes associated with PmLS5082 were profiled, and six genes in PmLS5082 interval were confirmed to be associated with PmLS5082 via RT-qPCR, using an additional set of wheat samples and time-course analysis post-inoculation with Bgt. In order to transfer PmLS082 to different genetic backgrounds using marker-assisted selection (MAS), closely linked markers, including Kompetitive Allele-Specific PCR (KASP) markers, were evaluated and nine markers were confirmed to be widely applicable for MAS in different genetic backgrounds.

Compact four-band diplexer using defected ground structures

In this paper, a novel four-band diplexer using defected ground structures with compact size, low insertion loss and high isolation is presented. To begin with, there are 16 defected ground stepped impedance resonators (DSIRs) controlling four passbands characteristics. Every four DSIRs can generate one passband. Then, four different DSIRs use the same feeding line. According to the group delay, we can determine the relative physical position of the first resonator. For the demonstration, a four-band diplexer operating at 2.45/4.2 and 3.5/5.2 GHz with the fractional bandwidths of 10, 7, 6.2 and 5% is designed and fabricated. Finally, measured results agree well with simulated results.

Using Probabilistic Genotypes in Linkage Analysis of polyploids

Marker genotypes are generally called as discrete values: homozygous versus heterozygous in the case of diploids, or an integer allele dosage in the case of polyploids. Software for linkage map construction and/or QTL analysis usually relies on such discrete genotypes. However, it may not always be possible, or desirable, to assign definite values to genotype observations in the presence of uncertainty in the genotype calling. Here, we present an approach that uses probabilistic marker dosages for linkage map construction in polyploids. We compare our method to an approach based on discrete dosages, using simulated SNP array and sequence reads data with varying levels of data quality. We validate our approach using experimental data from a potato (Solanum tuberosum L.) SNP array applied to an F1 mapping population. In comparison to the approach based on discrete dosages, we mapped an additional 562 markers. All but three of these were mapped to the expected chromosome and marker position. For the remaining three markers, no physical position was known. The use of dosage probabilities is of particular relevance for map construction in polyploids using sequencing data, as these often result in a higher level of uncertainty regarding allele dosage.

Karl Bühler’s Fantasmatic Deixis Between Motion, Gestures, and Words

SummaryWhat is the “fantasmatic deixis”? It is a very creative and productive cognitive–linguistic operation that allows a “transfer” to other real or fantastic times, places, and “worlds”. The underlying psychological question concerns the possibility of moving and being moved with respect to something or someone who is absent (Bühler, 1965). This “fiction game” is made possible by deictic indicators (Tenchini, 2008), terms that allow motion in time and space, always considering the here–now–I system of subjective orientation. When we refer to something that can be gathered by hearing or by sight, by terms such as here, there, I, and you, the receiver can easily use natural, prelinguistic aids (e.g., gestures, voice quality, facial expressions, and body orientation) to understand what the issuer intends to communicate to him (demonstratio ad oculos). But what happens when we move from the study of “immediate” behavior to that of “mediate” behavior, i.e., the field of memories (retrospection) or the constructive fantasy (prospecting)? The fantasmatic deixis implies enfranchisement from the physical position of the body and requires the assumption of the listener’s current tactile body image. Thus, the receiver assumes an inner attitude to correctly interpret the indications given by the speaker, seeing and hearing through the “inner” or “mental” eye and ear (Raynaud, 2006). In this way, the listener can bring something absent in his/her here, now, and I or feel moved to the point where the speaker leads him/her. My paper will focus on the features and types of fantasmatic deixis, providing some examples and showing how this operation involves language, motion, and cognitive processes.

Optimization of MOEMS Projection Module Performance with Enhanced Piezoresistive Sensitivity

In scanning laser projection systems, the laser modulation time is important for the projection resolution. The modulation time needs to be matched with the motion of the micromirror. For this paper, the piezoresistive sensor was integrated on the torsion beam of the micromirror to monitor the physical position of the micromirror. The feedback signal was used to generate the zero-crossing time, which was used to estimate the physical position of the resonating mirror over time. The estimated position was affected by the zero-crossing time and the error directly influenced the definition of the projected image. By reducing the impurity concentration from 3 × 1018/cm3 to 1 × 1018/cm3 and increasing shear stress on piezoresistive sensor, the sensitivity of the piezoresistive sensor increased from 4.4 mV/V° to 6.4 mV/V° and the error of the image pixel reduced from 1.5 pixels to 0.5 pixels. We demonstrated that the image quality of an Optical-Microeletromechanical Systems (MOEMS) laser projection could be improved by enhancing the sensitivity of the piezoresistive sensor.

Coextensive space: virtual reality and the developing relationship between the body, the digital and physical space

Virtual Reality (VR) has traditionally required external sensors placed around a designated play space. In contrast, more recent wired and wireless systems, such as the Oculus Rift S (released in March 2019) and the Oculus Quest (released in May 2019) use cameras located on the outside of these devices to monitor their physical position. Users can now mark out a physical space that is then digitally tracked within their display. Once a play space has been established, users are alerted if they come close to breaching this boundary by the visual inclusion of a grid. Should this threshold be breached, the headset display shifts to an image of the surrounding concrete environment. We contend that physical space is increasingly being incorporated into the digital space of VR in a manner that meaningfully differs from older systems. We build our argument in the following way. First, the article explores how theories surrounding VR have implicated only a limited relationship with physical space. Second, the article introduces the concept of coextensive space as a way of understanding the developing relationship between the physical, digital and concrete reality enacted by current VR systems.