Науково-практичний коментар Кримінального процесуального кодексу України. Зразки процесуальних документів у кримінальному провадженні [станом на 21 лют. 2020 р.]

Науково-практичний коментар Кримінального процесуального кодексу України. Зразки процесуальних документів у кримінальному провадженні [станом на 21 лют. 2020 р.] / за заг. ред. Чернявського С. С. – Київ : Вид. дім «Професіонал», 2020. – 1288 с. – ISBN 978-966-370-351-0.Надано науково-практичний коментар Кримінального процесуального кодексу України, а саме зразки процесуальних документів у кримінальному провадженні. Науково-практичний коментар розрахований на суддів, прокурорів, слідчих, співробітників оперативних підрозділів та адвокатів для використання в практичній роботі, а також як навчальний посібник для студентів навчальних учбових закладів, які готують фахівців в галузі права.Provided a scientific and practical commentary on the Criminal Procedure Code of Ukraine, namely, samples of procedural documents in criminal proceedings. The scientific and practical commentary is designed for judges, prosecutors, investigators, employees of operational units and lawyers for use in practical work, as well as a textbook for students of educational institutions that train specialists in the field of law.Предоставлен научно-практический комментарий Уголовного процессуального кодекса Украины, а именно образцы процессуальных документов в уголовном производстве. Научно-практический комментарий рассчитан на судей, прокуроров, следователей, сотрудников оперативных подразделений и адвокатов для использования в практической работе, а также как учебное пособие для студентов учебных заведений, которые готовят специалистов в области права

Development of A Direct Penetrating Signal Compensator in A Distributed Reception Channel of A Surveillance Radar

General structure of a compensator of a direct penetrating signal in the diversed reception channel was developed. It is advisable to use the antenna and the receiver of the auxiliary diverted reception channel as an auxiliary antenna and an auxiliary channel. To be able to suppress the penetrating signal in the band of the receiving device of the surveillance radar, distance between the antennas should be up to 6 m. In general, the compensator of the penetrating signals should contain an adder in which the signals received by the main channel are added with the signals received by the auxiliary channel and sent through the amplifier with a corresponding complex transmission coefficient. The direct penetration signal compensator features the obligatory condition of adjusting the value of the complex transmission coefficient of the auxiliary channel signal amplifier. The direct penetration signal compensator is digital and uses the direct method of forming weighting coefficients without the use of feedback. To reduce the time of formation of weighting coefficients when using direct methods of calculation of the correlation matrix, the technology of parallel computational processes was used. The quality of operation of the direct penetrating signal suppression system in the diverted reception channel was evaluated. It was established that without the use of suppression of direct penetrating signals, their powerful response at the output of the matched filter mask weak echo signals. When using a direct penetrating signal in the main channel of the compensator, its response at the output of the matched filter is significantly reduced. This makes it possible to observe weak echoes against the background of a strong penetrating signal. The use of the developed direct penetrating signal compensator provides suppression of the direct penetrating signal from 57 dB to 70 d

Approaches to Visualising the Spatial Position of ‘Sound-objects’

In this paper we present the rationale and design for two systems (developed by the Integra Lab research group at Birmingham Conservatoire) implementing a common approach to interactive visualisation of the spatial position of ‘sound-objects’. The first system forms part of the AHRC-funded project ‘Transforming Transformation: 3D Models for Interactive Sound Design’, which entails the development of a new interaction model for audio processing whereby sound can be manipulated through grasp as if it were an invisible 3D object. The second system concerns the spatial manipulation of ‘beatboxer’ vocal sound using handheld mobile devices through already-learned physical movement. In both cases a means to visualise the spatial position of multiple sound sources within a 3D ‘stereo image’ is central to the system design, so a common model for this task was therefore developed. This paper describes the ways in which sound and spatial information are implemented to meet the practical demands of these systems, whilst relating this to the wider context of extant, and potential future methods for spatial audio visualisation.</div