Hướng phát triển của luận án

Các nội dung nghiên cứu của luận án có thể tiếp tục hoàn thiện và phát triển, một số hướng phát triển như sau:

i) Mở rộng nghiên cứu thử nghiệm nhận dạng với mô hình mạng tự điều chỉnh cấu hình mạng, tự điều chỉnh các tham số đầu vào, số lượng tham số thích nghị

ii) Nghiên cứu thử nghiệm với các mô hình lai ghép với mạng nơron tích chập và thẻ sinh trắc học.

iii) Tiếp cận hướng nghiên cứu nhằm đảm bảo độ chính xác trong nhận dạng khi ngữ liệu của môi trường thực không hoàn toàn như dữ liệu đã được học.

iv) Kết hợp việc nhận dạng hình ảnh, hành vi, tiếng nói và các giác quan để góp phần hướng tới xây dựng các hệ thống thông minh hoạt động hiệu quả.

v) Tiến tới xây dựng thuật toán học đầy đủ các tham số [A, B, I] cho mạng nơron tế bào bậc caọ

DANH MỤC CÁC CÔNG BỐ CỦA LUẬN ÁN

Ạ1. Nguyen Tai Tuyen, Nguyen Quang Hoan, Ngo Van Sy, (2016) “Stability of Multi-Interactive Cellular Neural Networks Using Lyapunov Function”, Hội thảo toàn quốc về Điện tử, Truyền thông và Công nghệ Thông tin REV-2016, pp.59- 61.

Ạ2. Nguyen Tai Tuyen, (2016) "On A Structure Of High Order Multi-Interaction Cellular Neural Network", International Journal of Advance Computational Engineering and Networking (IJACEN), pp. 24-26, Volume-4, Issue-2.

Ạ3. Tuyen Nguyen Tai, (2017) "On an Application of Multi-Interaction Cellular Neural Network in Smart Farms Systems", International Journal of Electrical, Electronics and Data Communication (IJEEDC), pp. 1-3, Volume-5, Issue-7. Ạ4. Nguyen Tai Tuyen, Nguyen Quang Hoan, (2018) “An Application of Multi-

Interaction Cellular Neural Network on the Basis of STM32 and FPGA”,

International Journal for Research in Applied Science & Engineering Technology (IJRASET), pp. 177-181, Volume-5, Issue-Ị

Ạ5. Tuyen Nguyen Tai, Hoan Nguyen Quang, (2018) “An Application of High Order Multi-Interaction Cellular Neural Network in Early Warning for Cardiovascular Disease Patients with Anti-Vitamin K”, International Journal of Research in Technology and Management, pp. 24-27, Volume-4, Issue-1.

Ạ6. Nguyen Tai Tuyen, Nguyen Quang Hoan, Ngo Van Sy, (2019) “On An Application of High Order MultiInteraction Cellular Neural Network in the Early Fire Warning System”, International Journal of Latest Engineering Science, pp. 53-58, Volume-2, Issue-6.

Ạ7. Nguyen Quang Hoan, Nguyen Tai Tuyen, Duong Duc Anh, (2020) “Architecture and Stability of the Second-Order Cellular Neural Networks”,

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PHỤ LỤC 1

CHỨNG MINH CÁC ĐỊNH LÝ CỦA MẠNG NƠRON TẾ BÀO [11]

Trước khi thiết kế một CNN vật lý, việc đầu tiên cần phải biết phạm vi động của mạng để đảm bảo rằng mạng sẽ thỏa mãn các giả định về các phương trình động học, yêu cầu đặt ra phải thỏa mãn các điều kiện được trình bày trong (1.33) của chương 1. Để đảm bảo nền tảng cho việc thiết kế mạng nơron tế bào, tác giả tiến hành xem xét các định lý trong [11], như saụ

Định lý 1

Định lý được Leon Ọ Chua phát biểu [11]. Tất cả các trạng thái xij trong CNN đều bị giới hạn với mọi thời gian t > 0 và điều kiện ràng buộc liên kết vmax được tính theo công thức sau cho các mạng nơron tế bào (1.37).

( ) x ( , ) ( , ) max 1 ( , ; , ) ( , ; , ) ma i j x x k l v  R I R A i j k l B i j k l      = + +  + (P1.1) Chứng minh

Để chứng minh, ta viết lại phương trình động động học của tế bào như sau:

( ) 1 ' ( ) ( ) ( ) ij ij ij ij x dx t x t f t g u I dt = −R C + + + 1 i M 1 j N (P1.2a) trong đó: ( , ) 1 ( ) ( , ; , ) ( ) ij k l kl f t A i j k l y t C =  1 i M 1 j N (P1.2b) ( , ) 1 ( ) ( , ; , ) ij kl k l g u B i j k l u C =  1 i M 1 j N (P1.2c) ' I I C = (P1.2d)

Cho 1 ( ) ij MN U E t 

 trong ma trận MN chiều có phương trình vectơ đầu vào không đổi (P1.2a) là phương trình bậc nhất và nó được cho bởi:

( ) (0) t R Cx ij ij x t x e − = + ( ) 0 ' ( ) ( ) ( ) ( ) t R Cx ij ij ij ij t e f h g u p u I d     − −       + + + + + (P1.3) Theo đó ta có: ( ) 0 ' ( ) (0) ( ) ( ) t t R Cx t R Cx ij ij ij ij x t x e e f g u I d    − − −        +  + + ( ) 0 ' (0) ( ) ( ) t t R Cx t R Cx ij ij ij x e e f g u I d    − − −        + + + ( ) 0 ' (0) t t R Cx t R Cx ij ij ij x e F G I e d   − − −  + +       +  xij(0) RxCFij +Gij + I'      + Ở đây: ( , ) 1 max ( ) ( , ; , ) max ( ) ij t ij k l t kl F f t A i j k l y t C =   (P1.4a) ( , ) 1 max ( ) ( , ; , ) max ij u ij u kl k l G g u B i j k l u C =   (P1.4b) Từ xij(0) và uij thỏa mãn các điều kiện trong trong (2d) và (2e) và yij( )t thỏa mãn điều kiện:

( ) 1

ij t

y  cho mọi thời gian t

Với đặc trưng được trình bày trong (2b) [11], tiếp theo là (P.3) và (P.4) ta có: xij( )t  xij(0) ( , ) ( , ; , ) max ( ) ( , ; , ) max x t kl u kl k l R  A i j k l y t B i j k l u I    +  + + ( ) ( , ) 1 x ( , ; , ) ( , ; , ) k l I R  A i j k l B i j k l  +      +  +

1 i M, 1 j N (P1.5) Dễ thấy: ( ) ( , ) ( , ) max 1 ( , ; , ) ( , ; , ) max x i j k l v  R I Rx A i j k l B i j k l      = + +  + (P1.6)

Do vmax không phụ thuộc vào thời gian t và tế bào C( , )i j với mọi i và j, ta có:

max ij

t

max x v 1 i M, 1 j N (P1.7) Với bất kỳ mạng nơron tế bào, các tham sốRx, C, I, ( , ; , )A i j k l , ( , ; , )B i j k l là