fa جداسازی طیفی با استفاده از الگوریتم HYCA بهبودیافته مقالات پردازش تصویر Paper پژوهشي Research <p dir="RTL" style="text-align: justify;"><span style="font-family:b nazanin;">تصویربرداری ابرطیفی ابزاری مهم در کاربردهای سنجش از دور به‌شمار می&shy;رود. حس‌گرهای ابرطیفی، نور منعکس‌شده از سطح زمین را در صدها و یا هزاران باند طیفی اندازه&shy;گیری می‌کنند. در بعضی از کاربردها، بی&shy;درنگ نیاز به داشتن تصویر در سطح زمین داریم که لازمه این موضوع، وجود پهنای باند زیاد بین حس‌گر و ایستگاه زمینی است. در بیش‌تر مواقع، پهنای باند ارتباطی بین ماهواره و ایستگاه زمینی کاهش می&shy;یابد و این امر، ما را مستلزم به استفاده از یک روش فشرده&shy;سازی می&shy;کند.<a name="OLE_LINK4"></a><a name="OLE_LINK3"> علاوه‌بر حجم بالای داده، مشکل دیگر در این تصاویر، وجود پیسکل&shy;های آمیخته است</a></span>. تجزیه و تحلیل پیکسل&shy;های آمیخته یا جداسازی طیفی، تجزیه پیکسل‌های آمیخته به مجموعه&shy;ای از اعضای پایانی و فراوانی&shy;های کسری آن&shy;هاست. به&shy;دلیل بالا‌بودن این حجم و به تبع آن، دشواربودن پردازش و تجزیه و تحلیل مستقیم این اطلاعات و البته قابل فشرده‌بودن این تصاویر، در سال&shy;های اخیر روش&shy;هایی تحت عنوان &laquo;حس‌گری&shy;فشرده و جداسازی&raquo; معرفی شده است. الگوریتم <span dir="LTR"><span style="font-size:8.0pt;">HYCA</span></span><span style="font-family:b nazanin;"> یکی از الگوریتم‌هایی است که با توجه به ویژگی‌های ذاتی تصاویر، سعی در فشرده&shy;سازی این تصاویر کرده است.<a name="OLE_LINK6"></a><a name="OLE_LINK5"> یکی از ویژگی‌های بارز این الگوریتم، سعی در استفاده از اطلاعات مکانی به‌منظور بازسازی بهتر داده‌ها است. در این پژوهش، روشی مطرح شده است که علاوه‌بر اطلاعات مکانی، از اطلاعات طیفی (پیکسل&shy;های غیرهمسایه) موجود در تصاویر، آن هم به‌صورت بی‌درنگ استفاده کند.</a></span> برای اضافه‌کردن اطلاعات غیر از پیکسل&shy;های همسایه، یک روش بخش&shy;بندی بی&shy;درنگ معرفی شده است که برای بخش&shy;بندی درست، میزان شباهت پیکسل&shy;ها در نظر گرفته می&shy;شود و شکل حاصله در هر بخش محدود به هیچ شکل هندسی خاصی نمی&shy;شود. برای ارزیابی میزان کارآیی روش پیشنهادی، در بخش نتایج از هر دو داده ابرطیفی ساختگی و واقعی استفاده شده است. علاوه بر آن، نتایج کار با یک سری روش&shy;های سنتی در این حوزه مقایسه شده است. نتایج به‌دست آمده حاکی از کارآیی بالای روش پیشنهادی در معیار <span dir="LTR"><span style="font-size:8.0pt;">NMSE</span></span><span style="font-family:b nazanin;"> تا </span><span style="position:relative;top:1.5pt;"><span style="font-family:calibri,sans-serif;"><span style="font-size:11.0pt;"> </span></span></span><span style="font-family:b nazanin;">&nbsp;برای داده ساختگی و </span><span style="position:relative;top:1.5pt;"><span style="font-family:calibri,sans-serif;"><span style="font-size:11.0pt;"> </span></span></span><span style="font-family:b nazanin;">&nbsp;برای داده واقعی است.</span><br> &nbsp;</p> <p style="text-align: justify;"><strong>Hyperspectral (HS) imaging is a significant tool in remote sensing applications. HS sensors measure the reflected light from the surface of objects in hundreds or thousands of spectral bands, called HS images. Increasing the number of these bands produces huge data, which have to be transmitted to a terrestrial station for further processing. In some applications, HS images have to be sent instantly to the station requiring a high bandwidth between the sensors and the station. Most of the time, the bandwidth between the satellite and the station is narrowed limiting the amount of data that can be transmitted, and brings the idea of Compressive Sensing (CS) into the minds. In addition to the large amount of data, in these images, mixed pixels are another issue to be considered. Despite of their high spectral resolution, their spatial resolution is low causing a mixture of spectra in each pixel, but not a pure spectrum. As a result, the analysis of mixed pixels or Spectral Unmixing (SU) technique has been introduced to decompose mixed pixels into a set of endmembers and abundance fraction maps. The endmembers are extracted from spectral signatures related to different materials, and the abundance fractions are the proportions of the endmembers in each pixel. In recent years, due to the large amount of data and consequently the difficulties of real-time signal processing, and also having the ability of image compression, methods of Compressive Sensing and Unmixing (CSU) have been introduced. Two assumptions have been considered in these methods: the finite number of elements in each pixel and the low variation of abundance fractions.</strong><br> <strong>HYCA algorithm is one of the methods trying to compress these kinds of data with their inherent features.</strong><strong> One of the sensible characteristics of this algorithm is to utilize spatial information for better reconstruction of the data. In fact, HYCA algorithm splits the data cube into non-overlapping square windows and assumes that spectral vectors are similar inside each window. In this study, a real-time method is proposed, which uses the spectral information (<a name="OLE_LINK2"></a><a name="OLE_LINK1">non-neighborhood </a>pixels) in addition to the spatial information. The proposed structure can be divided into two parts: transmitting information into the satellites and information recovery into the stations.</strong><br> <strong>In the satellites, firstly, to utilize the spectral information, a new real-time clustering method is proposed, wherein the similarity between the entire pixels is not restricted to any specific form such as square window. Figure 3 shows a segmented real HS image. It can be seen that the considering square form limits the capability of the HYCA algorithm and the similarity can be found in the both neighborhood and non-neighborhood pixels. Secondly, to utilize similarity in each cluster, different measurement matrices are used. By doing this, various samples can be achieved for each cluster and further information are extracted. On the other hand, usage of different measurement matrices may affect the system stability. As a matter of fact, generating the different measurement matrices is not simple and increases complexity into the transmitters. Therefore, it conflicts with the aim of CS theory, reducing complexity into the transmitters. As a result, in the proposed method, the number of the clusters is determined by the number of the producible measurement matrices. Figure 4 shows the schematic of the proposed structure in the satellites.</strong><br> <strong>In the stations, we follow HYCA procedure in equation 8 and 9, but the different similar pixels are applied to the both equations. By doing this, we reach to the improved HYCA algorithm. Finally, the proposed structure is shown in the Table 1.</strong><br> <strong>To evaluate the proposed method, both real and simulated data have been used in this article. In addition, normalized mean-square error is considered as an error criteria. For the simulated data, in constant measurement sizes, the effects of the additive noise, and for real data, the effects of measurement sizes have been investigated. Besides, the proposed method has been compared with HYCA and C-HYCA and some of the traditional CS based methods. The experimental results show the superiority of the proposed method in terms of signal to noise ratios and the measurement sizes, up to </strong> <strong>&nbsp;in the simulated data and </strong> <strong>&nbsp;in the real data, which makes it suitable in the real-world applications.</strong><br> &nbsp;</p> اطلاعات طیفی و مکانی, الگوریتم HCYA, تصاویر ابرطیفی, جداسازی طیفی, حس‌گری‌فشرده Compressive Sensing (CS), HYCA algorithm, hyperspectral imaging, spatial and spectral information, spectral unmixing 37 50 http://jsdp.rcisp.ac.ir/browse.php?a_code=A-10-752-1&slc_lang=fa&sid=1 Farshid Khajeh Rayeni فرشید خواچه راینی farshid.khajehrayeni@modares.ac.ir 10031947532846006038 10031947532846006038 No دانشگاه تربیت مدرس Hassan Ghassemian محمد حسن قاسمیان ghassemi@modares.ac.ir 10031947532846006039 10031947532846006039 Yes دانشگاه تربیت مدرس