السبت، 19 مايو 2012

Electric Power Systems Planning







Electricity is so basic to the world economy that certain electricity indices are used to express a country’s economic standing (consumption or production of electricity per capita) and the standard of living enjoyed by a people (per capita electricity consumption in the domestic sector). Moreover, electricity supply has special characteristics which make the service unique as compared to other types of industry. The end product has to be delivered instantaneously and automatically upon the consumer’s demand; except for pumped storage plants and Electric batteries, technologies do not exist that can produce it economically at uniform rates, hold it in storage in large quantities, and deliver it under convenient schedules; insufficient capacity (shortage) or excessive capacity (idle capacity)
have negative effects on the economy; the close inter-relation with economic and social factors imposes labour, environmental, financial and other constraints on the problem. Careful Planning of the Electric sector is therefore of great importance since the decisions to be taken involve the commitment of large resources, with potentially serious economic risks for the electrical utility and the economy as a whole
Power system Planning is part of a more general problem, that of energy and economic development planning. Its objective is therefore to determine a minimum cost strategy for long-range expansion of the generation, transmission and distribution Systems adequate to supply the load forecast within a set of technical, economic and political constraints. Traditionally, Power system Planning has been mainly related to generation expansion planning. This is due mainly to the fact that investment in transmission lines is a relatively small fraction of the investment in the construction of Power stations and that investment in the distribution of Electric energy to customers, although sizeable, is to a large extent independent of the generation and transmission system.
The main steps in Power system Planning may be summarized as follows:
(a) Study of the Electric load forecast 5 to 30 years into the future, based on the most reliable information
Evaluation of the energy resources available in the future for electricity generation
and the foreseeable trends in technical and economic developments.
(c) Evaluation of the economic and technical characteristics of the existing system of generating units and of the plants that are considered as potential units for system expansion. These characteristics include capital investment cost, fuel cost,operation and maintenance costs, efficiencies, construction times, etc.
(d) Determination of technical and cost characteristics of the plants available for
expansion.
(e) Determination of the economic and technical parameters affecting decisions such as discount rate, level or reliability required from the generating system, etc.
(f) Choice of a procedure to determine the optimal expansion strategy within the
imposed constraints.
 
  (g) Qualitative review of the results to estimate the viability of the proposed solution

DC-DC converters






DC-DC converters are electronic devices used whenever
we want to change DC electrical power efficiently from
one voltage level to another. They’re needed because unlike
AC, DC can’t simply be stepped up or down using a
transformer. In many ways, a DC-DC converter is the DC
equivalent of a transformer.
Typical applications of DC-DC converters are where 24V
DC from a truck battery must be stepped down to 12V DC
to operate a car radio, CB transceiver or mobile phone;
where 12V DC from a car battery must be stepped down
to 3V DC, to run a personal CD player; where 5V DC on a
personal computer motherboard must be stepped down to
3V, 2V or less for one of the latest CPU chips; where the
340V DC obtained by rectifying 240V AC power must be
stepped down to 5V, 12V and other DC voltages as part of
a PC power supply; where 1.5V from a single cell must be
stepped up to 5V or more, to operate electronic circuitry;
where 6V or 9V DC must be stepped up to 500V DC or
more, to provide an insulation testing voltage; where 12V
DC must be stepped up to +/-40V or so, to run a car hifi
amplifier’s circuitry; or where 12V DC must be stepped up
to 650V DC or so, as part of a DC-AC sinewave inverter.
DC-DC converters
 
Eng.Snsn.Ahmad 

كشف الأشارة المتتابعة المباشرة للطيف المنتشر بالأعتماد على نظرية الفوضى



Direct Sequence Spread Spectrum Signal Detection  Based On Chaos Theory
كشف الأشارة المتتابعة المباشرة للطيف المنتشر بالأعتماد على نظرية الفوضى



                                                                    
Abstract
       “Weak Signal detection (WSD)” usually means that obtaining useful information of weak signal in a strong noise with detection tools. The objective of this paper is to study and introduce a method to detect direct sequence spread spectrum signals (DS-SSS) applying chaos theory by using one type of chaotic equation called Duffing – Holmes equation to model Duffing – Holmes oscillator. The detection depends on changing the phase plane from the chaotic shape to the periodic one, so after adding the signal to be detected (with the same interior frequency) and AWGN noise addition, if the phase plane is changed to periodic, this means that a signal is detected.To recognize detection, a proposed method named "rectangular-method" which depends on calculating the percentage of the points in a virtual rectangle to the total points introduced from numerical solution of the Duffing –Holmes equation of oscillator.  A bank of oscillators was used with certain frequency spacing between them to cover DSSS bandwidth.                
        The results obtained in simulation tests reached to detection with SNR down to (-60dB)  detection with probability of detection of (96%) and probability of false alarm (1%).
 
الخلاصة:
كشف الأشارة الضعيفة (WSD)دائما يعني أنه يمكن الحصول على معلومات للأشارة الضعيفة بوجود أشارة ضوضاء قوية بأستخدام وسائل الكشف . أن الهدف من هذا البحث هو دراسة وأستنتاج طريقة لكشف أشارة المتتابعة المباشرة للطيف المنتشر (DS-SSS) بتطبيق نظرية الفوضى. بأستخدام أحد أنواع المعادلات الفوضوية والتي تدعى معادلة (Duffing – Holmes)تم عمل نموذج لمذبذب من نفس النوع. أن عملية الكشف تعتمد على تغير مستوى الطور من الشكل الفوضوي الى الشكل الدوري , لذا فبعد أضافة الأشارة المطلوب كشفها والتي تكون بنفس التردد الداخلي مع الضوضاء,فأ ن التحول في مستوى الطور الى الشكل الدوري يعني أن الأشارة كشفت.لأستدراك الكشف هنالك طريقة مقترحة سميت"طريقة المستطيل"تعتمد على حساب نسبة النقاط داخل مستطيل أفتراضي الى جميع النقاط الناتجة من الحل العددي للمعادلة الممثلة للمذبذب. تم أستخدام حزمة من المذبذبات يفصل بينها تردد محدد لتغطية حزمة واسعة من الترددات الخاصة بأشارة (DS-SSS).
توصلت النتائج المتحصلة من خلال أختبارات المحاكاة الى كشف الأشارة بنسبة أشارة الى ضوضاء قدرها(-60dB) مع أحتمالية كشف (96%) وأحتمالية أنذار كاذب (1%).



 Eng.Snsn.Ahmad