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৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]

পরীক্ষা৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]তারিখতারিখ অনির্ধারিতসময়01 hr 30 mins
মোট প্রশ্ন১১০
সিলেবাস
Full Model Test - 3
ঘনত্ব
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উত্তরিতবর্তমানপুনরায় দেখুনঅসম্পূর্ণ

৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২]

৪৯তম বিসিএস ⎯ তথ্য ও যোগাযোগ প্রযুক্তি (EEE) [ ৮৯২] · তারিখ অনির্ধারিত · ১১০ প্রশ্ন

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'Amend' এর বাংলা পরিভাষা কোনটি?
  1. ক্ষতিপূরণ দান করা
  2. সংশোধন করা
  3. সংবেদনশীল
  4. পরিবর্ধন করা
ব্যাখ্যা

• 'Amend' এর বাংলা পরিভাষা - সংশোধন করা।

অন্যদিকে,
• 'Amenable' অর্থ - সংবেদনশীল; চালিত বা নিয়ন্ত্রিত হতে আগ্রহী এমন; বাধ্য; অনুগত।
• 'Amends' অর্থ - ক্ষতিপূরণ দান করা।
• 'Augmenting' অর্থ - পরিবর্ধন করা।

উৎস: বাংলা একাডেমি, প্রশাসনিক পরিভাষা এবং অভিগম্য অভিধান।

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'বাতাস' শব্দের সমার্থক শব্দ কোনটি?
  1. উদক
  2. হিমানী
  3. প্রভঞ্জন
  4. পায়োদ
ব্যাখ্যা

• 'বাতাস' শব্দের সমার্থক শব্দ:
বায়ু, হাওয়া, পবন, সমীর, সমীরণ, অনিল, মরুৎ, প্রভঞ্জন।

অন্যদিকে,
• 'পানি' শব্দের সমার্থক শব্দ: অম্বু, জল, নীর, সলিল, অপ, উদক, তোয়, জীবন ইত্যাদি।
• 'তুষার' শব্দের সমার্থক শব্দ: বরফ; হিমানী; নীহার।
• 'মেঘ' শব্দের সমার্থক শব্দ: জলধর; জীমূত; বারিদ; নীরদ; পায়োদ; ঘন।

উৎস: বাংলা একাডেমি, আধুনিক বাংলা অভিধান; অভিগম্য অভিধান এবং ভাষা-শিক্ষা, ড. হায়াৎ মামুদ।

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আঠার শতকের শ্রেষ্ঠ কবি ছিলেন-
  1. বিদ্যাপতি
  2. চণ্ডীদাস
  3. মুকুন্দরাম চক্রবর্তী
  4. ভারতচন্দ্র রায়
ব্যাখ্যা

• ভারতচন্দ্র রায়:
- কবি রায়গুণাকর ভারতচন্দ্র আঠার শতকের শ্রেষ্ঠ কবি। তিনি মধ্যযুগের বাংলা সাহিত্যের অন্যতম শ্রেষ্ঠ কবি হিসেবেও মর্যাদার অধিকারী। মঙ্গলকাব্য ধারার শেষ কবি ভারতচন্দ্র বিদ্যাসুন্দর কাহিনিরও শ্রেষ্ঠ কবি রূপে পরিগণিত।

- কবি ভারতচন্দ্রের প্রতিভার শ্রেষ্ঠ নিদর্শন 'অন্নদামঙ্গল' কাব্য। 'কালিকামঙ্গল' ও 'বিদ্যাসুন্দর' এই কাব্যের অংশমাত্র।
- ভারতচন্দ্র ছিলেন 'ব্যাকরণ অভিধান সাহিত্য নাটক অলঙ্কার সঙ্গীত শাস্ত্রের অধ্যাপক এবং পুরাণ-আগম-পারসী-নাগরী -বেত্তা।'

- ভারতচন্দ্রের জন্মকাল নিয়ে মতানৈক্য আছে। ঈশ্বরগুপ্ত কর্তৃক উল্লেখিত ১৭১২ সাল সঠিক জন্মসাল নয়। বিভিন্ন তথ্য ও অনুমান মিলিয়ে সিদ্ধান্ত করা হয়েছে যে, ভারতচন্দ্র আঠার শতকের গোড়ার দিকে ১৭০৫ থেকে ১৭১০ সালের মধ্যে জন্মগ্রহণ করেছিলেন। ড. আশুতোষ ভট্টাচার্য সর্বশেষ তথ্য বিবেচনা করে ১৭০৭ সালে ভারতচন্দ্রের জন্ম হয়েছিল বলে মনে করেন। রায়গুণাকর ভারতচন্দ্র বর্তমান বর্ধমান বিভাগের ভুরসুট পরগনায় আধুনিক হাওড়া জেলার পেঁড়ো (পান্ডুয়া) গ্রামে জন্মগ্রহণ করেন।

- চল্লিশ বৎসর বয়সে ভারতচন্দ্র নবদ্বীপের রাজা কৃষ্ণচন্দ্র রায়ের সভাকবি নিযুক্ত হন। তাঁর মাসিক বেতন হয় চল্লিশ টাকা। কবি মহারাজ কৃষ্ণচন্দ্রকে প্রতিদিন কবিতা রচনা করে শোনাতেন। তাঁর কবিত্বে মুগ্ধ হয়ে রাজা তাঁকে 'গুণাকর' উপাধি প্রদান করেন এবং প্রচুর ভূসম্পত্তি উপহার দেন।

- ভারতচন্দ্র মহারাজ কৃষ্ণচন্দ্রের আদেশে 'অন্নদামঙ্গল' কাব্য রচনা করেন। কবি গ্রন্থোৎপত্তি সম্পর্কে বলেছেন যে, একদিকে দেবীর আদেশ, অন্যদিকে রাজার আদেশে কাব্য রচনা করেছেন।

অন্যদিকে,
• বিদ্যাপতি ছিলেন মিথিলার কবি। মিথিলার রাজসভার কবি বিদ্যাপতি মৈথিলি ভাষায় সুন্দর পদাবলি ও অন্যান্য গীতিকবিতা রচনা করে সকলকে মুগ্ধ করেছেন বলে তাঁকে 'মৈথিল কোকিল' বলা হয়। তিনি ছিলেন ব্রজবুলি বৈষ্ণব কবি এবং পদসঙ্গীত ধারার রূপকার। তাঁর শ্রেষ্ঠ কীর্তি হচ্ছে ব্রজবুলিতে রচিত রাধাকৃষ্ণ বিষয়ক পদ।

• চণ্ডীদাস চৈতন্যপূর্ব যুগের কবি ছিলেন। চণ্ডীদাসকে বাংলা ভাষার প্রথম মানবতাবাদী কবি বলা হয়।

• মুকুন্দরাম চক্রবর্তীর উপাধি ছিল কবিকঙ্কন।মধ্যযুগের বাংলা সাহিত্যে মানব রসের তিনি প্রথম এবং একমাত্র স্রষ্টা। মুকুন্দরাম চক্রবর্তীকে দুঃখ-বর্ননার কবি হিসাবেও আখ্যায়িত করা হয়।

উৎস: বাংলা সাহিত্যের ইতিহাস, ড. মাহাবুবুল আলম।

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যোগতন্ত্রশাস্ত্র মতে 'মীননাথ' চর্যাপদের কোন কবির অপর নাম?
  1. কাহ্নপা
  2. ভুসুকুপা
  3. লুইপা
  4. শবরপা
ব্যাখ্যা

• লুইপা:
- 'চয্যাচর্যবিনিশ্চয়'-এর প্রথম কবি লুইপা। তিব্বতি ঐতিহ্যে প্রাপ্ত চুরাশি জন সিদ্ধাচার্যের নামের তালিকায় লুইয়ের নাম আদিতম। অনেক পণ্ডিত লুইপাকে প্রথম চর্যাগীতি রচয়িতা বলে মনে করেন। তাঁর জীবনকাল ৭৩০-৮১০ খ্রিষ্টাব্দের মধ্যে। সে সময় ছিল রাজা ধর্মপালের রাজত্বকাল। হিন্দিভাষীরা লুইপাকে মগধ বা বিহারের অধিবাসী বলে দাবি করেন।

- যোগতন্ত্রশাস্ত্রেও লুইপার উল্লেখ রয়েছে। তন্ত্রশাস্ত্রের লুইপার অন্য নাম মীননাথ বা মৎস্যেন্দ্রনাথ। মৎস্যের সঙ্গে নামের মিল থাকায় কোনো কোনো পণ্ডিত লুইকে শবরপা-এর শিষ্য ও ধীবর সম্প্রদায়ের অন্তর্ভুক্ত বলে উল্লেখ করেন। এ লুইপা আদি সিদ্ধাচার্য (সকল সিদ্ধাচার্যের গুরু) বলে অনেকের ধারণা।

- লুইপাকে সংস্কৃত টীকাকার মুনি দত্ত আদি সিদ্ধাচার্য বলে উল্লেখ করেছেন। তবে, তারানাথের মতে, লুইপা চতুর্থ সিদ্ধাচার্য, আর সরহ হলেন আদি সিদ্ধাচার্য। তাঁর মতে, লুইপা ছিলেন উড্ডীয়ান-রাজ উদয়নের কর্মচারী। তিনি শবর পা-র শিষ্যত্ব গ্রহণ করেছিলেন। চর্যাগীতির লুইপা আর তন্ত্রশাস্ত্রের লুইপা অভিন্ন নয় বলেই মনে করা হয়। কেননা বলা হয়েছে, লুইপা ছিলেন গৌড় অঞ্চলের অধিবাসী। আর তন্ত্রশাস্ত্রের মীননাথ বা মৎস্যেন্দ্রনাথের বাড়ি দক্ষিণবঙ্গে। তিনি ছিলেন গোরক্ষনাথের গুরু। তাই ধারণা করা হয়, লুইপা ও মীননাথ অভিন্ন ব্যক্তি নয়।

- হরপ্রসাদ শাস্ত্রীর ধারণা লুইপা ছিলেন বাঙালি। রাহুল সাংস্কৃত্যায়নের মতে, লুইপা রাজা ধর্মপালের সচিব হিসেবে দায়িত্ব পালন করেন।

- লুইপা বহু গ্রন্থ রচনা করেছেন। তিব্বতি অনুবাদের মাধ্যমে লুইয়ের বৌদ্ধ দর্শন বিষয়ক তিনটি গ্রন্থের নাম পাওয়া যায়। এগুলো হলো: 'শ্রীভগবদভিসময়', 'অভিসময়বিভঙ্গ' ও 'তত্ত্বস্বভাবদোহাকোষগীতিকাদৃষ্টিনাম'। প্রথম দুটি বই দর্শনের এবং তৃতীয়টি দোঁহা ও গানের।

উৎস: বাংলা সাহিত্যের ইতিহাস, ড. মাহাবুবুল আলম।

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"সবাই এসো আলোর মিছিলে হে নবীন তরুণ দল।" এখানে 'মিছিল' কোন ভাষার শব্দ?
  1. বাংলা
  2. ফারসি
  3. ওলন্দাজ
  4. ফরাসি
ব্যাখ্যা



মিছিল (বিশেষ্য পদ),
- এটি ফারসি ভাষার শব্দ।
অর্থ:
- শোভাযাত্রা (মহরমের মিছিল)।
- মোকদ্দমা ও তৎসম্বন্ধীয় নথিপত্র।
- বিন্যাস, সিজিল।
- সমান, সমকক্ষ।

• ফারসি ভাষা থেকে আগত কিছু শব্দ হলো:
গ্রেপ্তারি, গ্রেফতার, দারোগা, দারোয়ান, সাদা, খরগোশ, কাজি, খোয়াব, চেহারা, কাগজ, চশমা, চাকর, চারপায়, ছয়লাপ ইত্যাদি।

উৎস: বাংলা একাডেমি, আধুনিক বাংলা অভিধান।

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ধ্বনি উৎপাদনের মূল উৎস-
  1. নাসিকা
  2. মুখ
  3. ফুসফুস
  4. কণ্ঠ
ব্যাখ্যা

• ধ্বনি:
- ভাষার ক্ষুদ্রতম একক ধ্বনি। কোনো ভাষার উচ্চারিত শব্দকে সূক্ষ্মভাবে বিশ্লেষণ করলে তার যে অবিভাজ্য ক্ষুদ্রতম অংশ পাওয়া যায়, তা-ই ধ্বনি। মানুষের বাগ্‌যন্ত্রের সহায়তায় উচ্চারিত ধ্বনি থেকেই ভাষার সৃষ্টি। বস্তুত ভাষাকে বিশ্লেষণ করলে চারটি মৌলিক উপাদান পাওয়া যায়। এই উপাদানগুলো হলো-ধ্বনি, শব্দ, বাক্য ও অর্থ।

- মানুষ তার মনের ভাব প্রকাশ করার জন্য 'কথা' বলে। মানুষের 'কথা' হলো অর্থযুক্ত কিছু ধ্বনি। ব্যাকরণ শাস্ত্রে মানুষের কণ্ঠনিঃসৃত শব্দ বা আওয়াজকেই ধ্বনি বলা হয়। বস্তুত অর্থবোধক ধ্বনিসমূহই মানুষের বিভিন্ন ভাষার বাধ্বনি। ধ্বনিই ভাষার মূল ভিত্তি।

- ধ্বনি নির্গত হয় মুখ দিয়ে। ধ্বনি উৎপাদনে মুখ, নাসিকা, কণ্ঠ প্রভৃতি বাক্-প্রত্যঙ্গ ব্যবহৃত হলেও ধ্বনি উৎপাদনের মূল উৎস হলো ফুসফুস। ফুসফুসের সাহায্যে আমরা শ্বাস গ্রহণ ও ত্যাগ করি। ফুসফুস থেকে বাতাস বেরিয়ে আসার সময় বিভিন্ন বাক্-প্রত্যঙ্গের সংস্পর্শে আসে। ফুসফুস থেকে বাতাস স্বরযন্ত্রের মধ্য দিয়ে বেরিয়ে আসার সময় মুখের বিভিন্ন জায়গায় ঘষা খায়। এই ঘর্ষণের ফলে মুখে নানা ধরনের ধ্বনির সৃষ্টি হয়।

- অর্থাৎ ফুসফুস নির্গত বাতাস স্বরযন্ত্রের মধ্য দিয়ে মুখগহ্বরে প্রবেশের পর বিভিন্ন বাক্-প্রত্যঙ্গের সংস্পর্শে আঘাত লাগার দরুন ধ্বনি গঠিত বা তৈরি হয়। ধ্বনি গঠনে বিভিন্ন বাক্- প্রত্যঙ্গের ভূমিকা অত্যন্ত গুরুত্বপূর্ণ।

উৎস: বাংলা ব্যাকরণ ও নির্মিতি, সপ্তম শ্রেণি।

.
'ঘরানা' শব্দটি কোন প্রত্যয় যোগে গঠিত?
  1. সংস্কৃত তদ্ধিত প্রত্যয়
  2. বাংলা তদ্ধিত প্রত্যয়
  3. সংস্কৃত কৃৎ প্রত্যয়
  4. বিদেশি তদ্ধিত প্রত্যয়
ব্যাখ্যা

• আনা (য়ানা) -আনি (য়ানি) বিদেশি তদ্ধিত প্রত্যয়: ভাব, অভ্যাস বা আচরণ অর্থে বিশেষ্য শব্দ গঠন করে।
যেমন:
ঘর + আনা = ঘরানা,
গরিব + আনা = গরিবানা,
বাবু + আনা = বাবুয়ানা,
বিবি + আনা = বিবিয়ানা ইত্যাদি।

আবার,
বাবু + আনি = বাবুআনি > বাবুয়ানি।

• এরূপ কিছু বিদেশি তদ্ধিত প্রত্যয় হলো-
-ওয়ান, -খানা, -খোর, -গর, -গিরি, -চা > চি, -চী > চি, -তর (তরো), -দান, -দানি, -সার, -নবিশ, -বন্দি, -বাজ /-বাজি, -সহি, সই, -স্তান।

উৎস: ভাষা-শিক্ষা, ড. হায়াৎ মামুদ।

.
যুক্তবর্ণের অশুদ্ধ গঠন কোনটি?
  1. জ্‌ + ঞ = জ্ঞ
  2. ঞ্‌ + ক = ঙ্ক
  3. ঞ্‌ + জ = ঞ্জ
  4. ঞ্‌ + চ = ঞ্চ
ব্যাখ্যা

• যুক্তবর্ণের অশুদ্ধ গঠন- ঞ্‌ + ক = ঙ্ক।
- শুদ্ধরূপ: ঙ্‌ + ক = ঙ্ক।

---------------
• যুক্তবর্ণ:

একাধিক বর্ণ যুক্ত হয়ে যুক্তবর্ণ তৈরি হয়। যুক্ত হওয়া বর্ণগুলোকে দেখে কখনো সহজে চেনা যায়, কখনো সহজে চেনা যায় না। এদিক দিয়ে যুক্তবর্ণ দুই রকম: স্বচ্ছ ও অস্বচ্ছ।

গুরুত্বপূর্ণ কিছু যুক্তবর্ণ হলো-
- জ্‌ + ঞ = জ্ঞ;
- ঞ্‌ + জ = ঞ্জ;
- ঞ্‌ + চ = ঞ্চ;
- ঞ্‌ + ছ = ঞ্ছ;
- ষ্‌ + ণ = ষ্ণ।

উৎস: ভাষা-শিক্ষা, ড. হায়াৎ মামুদ।

.
'অনাবশ্যকীয় ব্যাপারে কৌতূহল ভালো নয়।' বাক্যে কোন ধরনের অশুদ্ধি ঘটেছে??
  1. বিশেষণের বাহুল্য প্রয়োগজনিত ভুল
  2. বহুবচনের অপপ্রয়োগজনিত অশুদ্ধি
  3. সমাস ঘটিত অশুদ্ধি
  4. বাচ্যজনিত অশুদ্ধি
ব্যাখ্যা

• বিশেষ্যের জায়গায় বিশেষণের কিংবা বিশেষণের বাহুল্য প্রয়োগজনিত ভুল:
বাক্যের মধ্যে ব্যবহৃত বিশেষ্য পদকে বিশেষণ কিংবা বিশেষণ পদকে বিশেষ্য ভেবে পদ পরিবর্তন করলে এ ধরনের ভুল হয়।
যেমন- আবশ্যক শব্দটি বিশেষণ হিসেবে ব্যবহৃত হয়। এর বদলে ঈয় প্রত্যয় যোগ করে আবশ্যকীয় শব্দের ব্যবহার যথাযথ নয়।
যেমন
অশুদ্ধ: অনাবশ্যকীয় ব্যাপারে কৌতূহল ভালো নয়।
শুদ্ধ: অনাবশ্যক ব্যাপারে কৌতূহল ভালো নয়।

অশুদ্ধ: ইহার আবশ্যক নাই।
শুদ্ধ: হার আবশ্যকতা নাই।

অশুদ্ধ: রাঙ্গামাটি পার্বতীয় এলাকা।
শুদ্ধ: রাঙ্গামাটি পার্বত্য এলাকা।

অশুদ্ধ: বাংলাদেশ একটি উন্নতশীল দেশ।
শুদ্ধ: বাংলাদেশ একটি উন্নয়নশীল দেশ।

উৎস: ভাষা-শিক্ষা, ড. হায়াৎ মামুদ।

১০.
বিশেষণ পদ নয় কোনটি?
  1. নিখুঁত
  2. সুকঠিন
  3. দুঃসহ
  4. সততা
ব্যাখ্যা

• বিশেষণ পদ নয়- সততা।
- 'সততা' গুণবাচক বিশেষ্য পদ।

• আদ্য প্রত্যয় বা উপসর্গযুক্ত বিশেষণ: এ ধরনের বিশেষণ আদ্যপ্রত্যয় বা উপসর্গযোগে গঠিত হয়।
যেমন:
- নিখুঁত (নি + খুঁত) কাজ।
- সুকঠিন (সু + কঠিন) প্রতিজ্ঞা।
- দুঃসহ (দুঃ + সহ) দারিদ্র্য।

উৎস: ভাষা-শিক্ষা, ড. হায়াৎ মামুদ এবং বাংলা একাডেমি, আধুনিক বাংলা অভিধান।

১১.
নিচের কোন বানানটি অশুদ্ধ?
  1. প্রশস্ত
  2. অভ্যস্ত
  3. গৃহস্ত
  4. ব্যস্ত
ব্যাখ্যা

• শুদ্ধ বানান: গৃহস্থ।
- এটি বিশেষ্য পদ।
- সংস্কৃত ভাষার শব্দ।
অর্থ:
- সংসার ধর্ম পালন করে এমন,
- গৃহী।

অন্যদিকে,
• প্রশস্ত, অভ্যস্ত ও ব্যস্ত বানানগুলো শুদ্ধ।

• এরূপ কিছু শুদ্ধ শব্দ- ঠোঁটস্থ, মুখস্থ, দ্বারস্থ, অস্ত, কণ্ঠস্থ, গ্রস্ত।

উৎস: বাংলা একাডেমি, আধুনিক বাংলা অভিধান।

১২.
১৯৪৭ সালের দেশভাগকে কেন্দ্র করে রচিত উপন্যাস কোনটি?
  1. কালো ঘোড়া
  2. কালো বরফ
  3. খেলাঘর
  4. একটি কালো মেয়ের কথা
ব্যাখ্যা

• 'কালো বরফ' উপন্যাস:
- ১৯৭৭ সালের ২১-৩০ আগস্ট মাহমুদুল হক রচনা করেন 'কালো বরফ' উপন্যাসটি, কিন্তু এর প্রকাশকাল অনেক পরে ১৯৯২ সালে।
- এটি ছেচল্লিশের দাঙ্গা ও ১৯৪৭ সালের দেশভাগকে কেন্দ্র করে রচিত।
- উপন্যাসটিতে হিন্দু-মুসলমানের বিরোধ-দাঙ্গা, দ্বেষ-ক্ষোভ এবং মিলন-বিরহ পরিস্ফুটিত হয়েছে।
- উপন্যাসের প্রধান চরিত্র- আব্দুল খালেক।

অন্যদিকে,
-----------------
• 'খেলাঘর' (১৯৮৮): এটি মুক্তিযুদ্ধভিত্তিক উপন্যাস। চরিত্র: রেহানা, মুকল ও ইয়াকুব। ২০০৬ সালে উপন্যাসটির চলচ্চিত্রায়ন করা হয়।

• 'একটি কালো মেয়ের কথা' উপন্যাস: বাংলাদেশের স্বাধীনতা সংগ্রাম নিয়ে রচিত তারাশঙ্কর বন্দ্যোপাধ্যায়ের উপন্যাস- 'একটি কালো মেয়ের কথা'। এটি প্রকাশিত হয় ১৯৭১ খ্রিষ্টব্দে। এটি তাঁর সর্বশেষ উপন্যাস।

• "কালো ঘোড়া" লেখক ইমদাদুল হক মিলন রচিত একটি উপন্যাস। ১৯৮১ সালে পশ্চিম জার্মানির সিনডেল ফিঙেন শহরে বসে তিনি এই উপন্যাসটি রচনা করেন এবং এটি বাংলাদেশের একটি নিবিড় গ্রামকে কেন্দ্র করে আবর্তিত হয়। ‘কালোঘোড়া’ মুক্তিযুদ্ধের উপন্যাস। ১৯৭১ এর সেই জেগে ওঠার দিনে বাংলাদেশের একটি গ্রামে কেমন চেহারা নিয়েছিল মুক্তিযুদ্ধ, কেমন করে মুক্তিযুদ্ধ প্রভাবিত করেছিল গ্রামের প্রতিটি মানুষকে, কেমন করে মুক্তিযোদ্ধারা এসে আশ্রয় পায় এক বালকের কাছে, কেমন করে প্রাণ হারায় এব বোবা যুবতী, স্বাধীনতা বিরোধী চক্রের হোতা কেমন করে নিহত হয় মুক্তেোদ্ধাদের হাতে আর কেমন করেই বা মুক্তিযোদ্ধাদের আশ্রয়দাতা সেই বালক নিজের অজান্তে হয়ে ওঠে এক মহান মুক্তিযোদ্ধা, প্রাণের বিনিময়ে যে রক্ষা করতে চায় সহযোদ্ধাদের কে, এরকম অনেকগুলো বিষয়কে ‘কালোঘোড়া’ উপন্যাসে উপজীব্য করেছেন ইমদাদুল হক মিলন।

উৎস: 'কালো বরফ' ও "কালো ঘোড়া" উপন্যাস; বাংলা ভাষা ও সাহিত্য জিজ্ঞাসা এবং বাংলাপিডিয়া।

১৩.
'অপর্ণা' রবীন্দ্রনাথ ঠাকুরের কোন নাটকের চরিত্র?
  1. ডাকঘর
  2. মুক্তধারা
  3. বিসর্জন
  4. প্রায়শ্চিত্ত
ব্যাখ্যা

• 'বিসর্জন' নাটক:
- 'বিসর্জন' রবীন্দ্রনাথ ঠাকুর রচিত একটি নাটক। 'রাজর্ষি' উপন্যাসের প্রথমাংশ অবলম্বনে 'বিসর্জন' নাটকটি রচিত হয়।

- 'বিসর্জন' রবীন্দ্রনাথ ঠাকুরের মঞ্চসফল এবং জনপ্রিয় নাটকগুলির অন্যতম। রবীন্দ্রনাথ ঠাকুর স্বয়ং এই নাটকের প্রধান দুটি চরিত্র রঘুপতি ও জয়সিংহের ভূমিকায় বিভিন্ন সময়ে অভিনয় করেন।

- উদার ধর্মবোধ এবং সংকীর্ণ ধর্মীয় বিশ্বাসের মধ্যে দ্বন্দ্ব যেমন এই নাটকের প্রধান উপকরণ, তেমনই বিশ্বাসের উগ্রতা এবং মানব সম্পর্কের নিবিড়তা এই নাটকের প্রধান বৈশিষ্ট্য।
- রবীন্দ্রনাথ রচিত বিসর্জন নাটকে গোমতী নদীর কথা উল্লেখ আছে। নাটকটি অমিত্রাক্ষর ছন্দে রচিত।

উল্লেখযোগ্য চরিত্র:
- রঘুপতি,
- জয়সিংহ,
- অপর্ণা,
- গুণবতী,
- গোবিন্দমাণিক্য।

অন্যদিকে,
• 'ডাকঘর' নাটকের উল্লেখযোগ্য চরিত্র: অমল, সুধা, ঠাকুর্দা প্রমুখ।
• 'মুক্তধারা' নাটকের উল্লেখযোগ্য চরিত্র: অভিজিৎ, রণজিত, সুমন, অম্বা, বিভূতি।
• "প্রায়শ্চিত্ত" নাটকের চরিত্রগুলো: ধনঞ্জয়, সুরমা, উদয়াদিত্য, বিভা ইত্যাদি।

-------------------
তাঁর রচিত উল্লেখযোগ্য নাটক:
- রুদ্র চন্দ্র,
- বাল্মিকী প্রতিভা,
- কালের যাত্রা,
- তাসের দেশ,
- ডাকঘর,
- মালিনী ইত্যাদি।

উৎস: বাংলা ভাষা ও সাহিত্য জিজ্ঞাসা এবং বাংলাপিডিয়া।

১৪.
নিম্নের কত তারিখে অস্ট্রেলিয়া ফিলিস্তিনকে আনুষ্ঠানিকভাবে রাষ্ট্র হিসেবে স্বীকৃতি দিয়েছে?
  1. ২০ সেপ্টেম্বর, ২০২৫
  2. ২৩ সেপ্টেম্বর, ২০২৫
  3. ২২ সেপ্টেম্বর, ২০২৫
  4. ২১ সেপ্টেম্বর, ২০২৫
ব্যাখ্যা

• ফিলিস্তিনকে স্বীকৃতি:
- ২১ সেপ্টেম্বর, ২০২৫ যুক্তরাজ্য, কানাডা, অস্ট্রেলিয়া ও পর্তুগাল ফিলিস্তিনকে স্বীকৃতি দিয়েছে।
- বিশ্বের ধনী দেশগুলোর জোট জি-৭-এর সদস্যদের মধ্যে প্রথম ফিলিস্তিনকে স্বীকৃতি দিল যুক্তরাজ্য ও কানাডা।
- এর পর দিন ২২ সেপ্টেম্বর, ২০২৫ জাতিসংঘের সদর দপ্তর এক অনুষ্ঠানে ফিলিস্তিনকে আনুষ্ঠানিকভাবে রাষ্ট্র হিসেবে স্বীকৃতি দিয়েছে জাতিসংঘের নিরাপত্তা পরিষদের স্থায়ী সদস্য দেশ ফ্রান্স।
- এ নিয়ে জাতিসংঘের ১৯৩ সদস্যদেশের দেড় শ’র বেশি দেশ ফিলিস্তিনকে রাষ্ট্র হিসেবে স্বীকৃতি দিয়েছে।
- এর মধ্যে এশিয়া, আফ্রিকা, লাতিন ও মধ্য আমেরিকার দেশই বেশি।
- ১৯৮৮ সালের ১৬ নভেম্বর ফিলিস্তিনকে স্বীকৃতি দেয় বাংলাদেশ।
- জাতিসংঘের নিরাপত্তা পরিষদের স্থায়ী পাঁচ সদস্যের মধ্যে ফিলিস্তিন রাষ্ট্রকে এ পর্যন্ত শুধু যুক্তরাষ্ট্র স্বীকৃতি দেয়নি।

সূত্র- প্রথম আলো পত্রিকা প্রতিবেদন।

১৫.
যুক্তরাষ্ট্রের 'ফেডারেল সিভিল সার্ভিস কমিশন' কত সালে গঠিত হয়?
  1. ১৮৮৩ সালে
  2. ১৮৮৫ সালে
  3. ১৮৮৭ সালে
  4. ১৮৮৯ সালে
ব্যাখ্যা

• ফেডারেল সিভিল সার্ভিস কমিশন:
- মার্কিন যুক্তরাষ্ট্রে সংবিধিবদ্ধভাবে ফেডারেল সিভিল সার্ভিস কমিশন গঠিত হয় ১৮৮৩ সালে।
- The Pendleton Civil Service Reform Act-1883 এর মাধ্যমে।
- ১৯৭৮ সালে ফেডারেল সিভিল সার্ভিস কমিশনে সংস্কার করে একে তিনটি প্রতিষ্ঠানে বিকেন্দ্রীকরণ করা হয়। এগুলো হলো:
- অফিস অব দ্য পার্সোনেল ম্যানেজমেন্ট
- দ্য মেরিট সিস্টেম প্রোটেকশন বোর্ড
- দ্য ফেডারেল লেবার রিলেশন অথরিটি।

উৎস: অফিস অব দ্য পার্সোনেল ম্যানেজমেন্ট ওয়েবসাইট।

১৬.
‘জাপাদ-২০২৫’ নামক সামরিক মহড়া চালিয়েছে -
  1. রাশিয়া ও চীন
  2. জাপান ও ভারত
  3. চীন ও পাকিস্তান
  4. রাশিয়া ও বেলারুশ
ব্যাখ্যা

• জাপাদ-২০২৫:
- জাপাদ-২০২৫ হলো রাশিয়া ও বেলারুশের যৌথ সামরিক মহড়া।
- এই মহড়া ১২ সেপ্টেম্বর, ২০২৫ শুরু হয় এবং ১৭ সেপ্টেম্বর, ২০২৫ শেষ হয়।
- এই মহড়ায় প্রায় ১ লাখ সেনা অংশগ্রহণ করে, যার মধ্যে ভারী অস্ত্র, বোমারু বিমান, যুদ্ধজাহাজ এবং প্যারাট্রুপারদের সমন্বয়ে ব্যাপক সামরিক কৌশল প্রদর্শন করা হয়।
- যুক্তরাষ্ট্রসহ ২৩টি দেশের প্রতিনিধিরা মহড়া দেখতে বেলারুশে উপস্থিত ছিলেন।
- মহড়ার মূল উদ্দেশ্য ছিল সীমান্তবর্তী অঞ্চলে সম্ভাব্য আগ্রাসন প্রতিহত করার জন্য প্রস্তুতি প্রদর্শন।

তথ্যসূত্র- প্রথম আলো পত্রিকা প্রতিবেদন।

১৭.
In an RLC circuit, which of the following causes the circuit to behave more inductively as the frequency increases?
  1. The resistance
  2. The inductance
  3. The capacitance
  4. The reactance of the capacitor
ব্যাখ্যা

Explanation:

ক) The resistance
Resistance (R) is not frequency-dependent. It remains constant regardless of the frequency in an RLC circuit. It doesn't change with frequency, so it does not influence whether the circuit behaves more inductively or capacitively. Therefore, this option is incorrect.

খ) The inductance
Inductance (L) is the key here.
The inductive reactance XL=2πfL increases with frequency. As the frequency increases, the inductive reactance increases, making the circuit behave more inductively.
In simple terms: higher frequency = higher inductive reactance, and the inductor dominates the behavior of the circuit.
So, this is the correct answer because as frequency increases, the inductive reactance increases, causing the circuit to behave more inductively.

গ) The capacitance
Capacitance (C) has a different effect: it causes capacitive reactance to behave inversely with frequency.Capacitive reactance XC=1/2πfC  decreases with frequency. As frequency increases, the capacitive effect decreases. This means the capacitor has less of an influence on the circuit as the frequency goes up.
So, capacitance actually reduces the circuit's inductive behavior as the frequency increases, rather than increasing it.
Therefore, this option is incorrect.

ঘ) The reactance of the capacitor
Reactance of the capacitor XC​ decreases with an increase in frequency, as explained above. So, as frequency increases, the capacitive reactance becomes smaller, meaning the circuit becomes less capacitive and more inductive.
However, the reactance of the capacitor is a consequence of the capacitance, and it decreases with higher frequency. It doesn't increase the inductive behavior. Therefore, this option is also incorrect.

১৮.
In a parallel RLC circuit, at resonance, the total impedance is:
  1. Equal to the sum of the resistance and reactance
  2. Zero
  3. Equal to the resistance
  4. Infinite
ব্যাখ্যা

Explanation:
At resonance, the inductive reactance XL​ and capacitive reactance XC​ are equal in magnitude but opposite in phase. This causes them to cancel each other out.
When XL=XC​, the total reactance in the parallel circuit is zero. This leaves the resistance (R) as the only factor affecting the total impedance.
Impedance in a parallel circuit is the reciprocal of the total admittance (the sum of the individual admittances of the resistor, inductor, and capacitor). At resonance, the inductor and capacitor cancel out, so only the resistance contributes to the total impedance.
Thus, at resonance, the total impedance of the circuit is equal to the resistance (R).

 
Why the other options are incorrect:
ক) Equal to the sum of the resistance and reactance: This is incorrect because at resonance, the reactances cancel out, and the impedance is purely resistive.
খ) Zero: This would be true in a series RLC circuit at resonance, but in a parallel circuit, the impedance doesn't become zero. It becomes equal to the resistance.
ঘ) Infinite: This would happen if the resistance were infinite or the impedance of a purely inductive or capacitive circuit, but at resonance in a parallel RLC circuit, the impedance is finite and equal to the resistance.

১৯.
What is the relationship between the current and voltage in a purely capacitive AC circuit?
  1. The current leads the voltage by 90°
  2. The voltage leads the current by 90°
  3. The current and voltage are in phase
  4. The current and voltage are out of phase by 180°
ব্যাখ্যা

Explanation:
In a capacitive AC circuit, the current and voltage are not in phase.
The current in a capacitive circuit leads the voltage by 90°. This means that the peak current occurs a quarter of a cycle (90°) before the peak voltage.
The reason for this is that a capacitor opposes changes in voltage by storing and releasing energy in the form of electric fields. As the voltage across the capacitor changes, the current must adjust accordingly, and this results in the current leading the voltage.
Why the other options are incorrect:
খ) The voltage leads the current by 90°: This describes a purely inductive circuit, not a capacitive one. In inductive circuits, the voltage leads the current by 90°.
গ) The current and voltage are in phase: This is true in a resistive AC circuit, where current and voltage are in phase with each other.
ঘ) The current and voltage are out of phase by 180°: This would occur in a purely resistive circuit with a negative voltage, but it is not true for a capacitive circuit.

২০.
What is the impedance of a circuit consisting of a 8Ω resistor in series with a 6Ω inductor at a frequency of 60Hz?

  1. 15Ω
  2. 10Ω
  3. 12Ω
ব্যাখ্যা

Explanation:
Resistance (R) = 8Ω
Inductive reactance (XL) = 6Ω (as this is the impedance of the inductor at 60Hz, no need to calculate it)
Impedance of a Series R-L Circuit:
In a series R-L circuit, the total impedance Z is given by:

Z=sqrt{R2 + XL2}
​​Substitute the values:

Z=sqrt{82 + 62}
  = sqrt(64+36)
  =10Ω
The impedance of the circuit is 10Ω.

২১.
Which theorem is used to analyze circuits by reducing multiple sources to a single equivalent source?
  1. Superposition Theorem
  2. Thevenin’s Theorem
  3. Norton’s Theorem
  4. Maximum Power Transfer Theorem
ব্যাখ্যা

Explanation:
The Superposition Theorem is used to analyze circuits with multiple sources (voltage or current sources). It involves the following steps:
Consider each source separately, replacing all other sources with their internal impedance (voltage sources are replaced by short circuits, and current sources by open circuits).
Calculate the effect of each source individually on the circuit.
Sum the individual effects from each source to find the total response in the circuit.
This allows us to reduce a complex circuit with multiple sources into simpler parts.

Why the other options are incorrect:
খ) Thevenin’s Theorem: This theorem helps reduce a linear circuit with multiple sources to a single voltage source and a single series resistance (Thevenin equivalent). It's useful for simplifying circuits but not specifically for reducing multiple sources to a single equivalent source.
গ) Norton’s Theorem: This theorem is similar to Thevenin's Theorem but reduces the circuit to a single current source in parallel with a single resistance (Norton equivalent). Again, it's used for simplification but not exactly for analyzing multiple sources like the superposition theorem.
ঘ) Maximum Power Transfer Theorem: This theorem deals with finding the condition where maximum power is delivered to a load in a circuit, not reducing sources.

২২.
In a three-phase system, the total power is calculated by:
  1. P = √3 * V(line) * I(line)
  2. P = Vphase * Iphase
  3. P = V(line) * I(line)
  4. P = 3 * V(line) * I(line)
ব্যাখ্যা

Explanation:
The total power in a balanced three-phase system is calculated as P = √3 * V line * I line * cos(φ), where φ is the phase angle.

Reference Book:
*Power System Analysis* by John J. Grainger & William D. Stevenson, Chapter 5.

২৩.
The maximum power transfer theorem states that the maximum power is delivered to the load when:
  1. The load resistance is zero
  2. The load resistance is equal to the source resistance
  3. The load resistance is infinite
  4. The load resistance is half the source resistance
ব্যাখ্যা

Explanation:
The Maximum Power Transfer Theorem states that the maximum power is delivered to the load when the load resistance (RL) is equal to the source resistance (Rs). Mathematically:

RL​=Rs , ​When the load resistance matches the source resistance, the power transfer from the source to the load is maximized. This condition ensures that the voltage and current are optimally distributed across the load and source resistances.

Why the other options are incorrect:
ক) The load resistance is zero: If the load resistance is zero, it would create a short circuit, and no power would be transferred to the load. Power transfer requires the load to have some resistance.
গ) The load resistance is infinite: If the load resistance is infinite (open circuit), no current would flow, and thus, no power would be transferred to the load. Power transfer requires current to flow through the load.
ঘ) The load resistance is half the source resistance: This is incorrect. The maximum power occurs when the load resistance is equal to the source resistance, not half.

২৪.
In an AC circuit, the voltage is 200V, the current is 5A, and the phase angle between the voltage and current is 45°. What is the power factor?
  1. 0.5
  2. 0.707
  3. 1
  4. 0.866
ব্যাখ্যা

Explanation:
To calculate the power factor (PF), use the formula:

PF=cos⁡(θ)
Where θ=45

PF=cos⁡(45)=0.707
Thus, the power factor is 0.707.

২৫.
A transformer with a turns ratio of 10:1 has a primary voltage of 120V. What is the secondary voltage?
  1. 12V
  2. 240V
  3. 24V
  4. 2400V
ব্যাখ্যা

Explanation:
The voltage in a transformer is related to the turns ratio by the equation Vs = (Ns / Np) * Vp. For a 10:1 ratio, the secondary voltage will be Vs = (1/10) * 120V = 12V.

Reference Book:
*Electrical Machines* by Syed A. Nasar, Chapter 4.

২৬.
What is the time constant of an RC circuit?
  1. T = RC
  2. T = R / C
  3. T = 1 / RC
  4. T = C / R
ব্যাখ্যা

Explanation:
The time constant in an RC circuit is the product of the resistance R and the capacitance C, which determines how fast the voltage across the capacitor changes.

Reference Book:
*Electrical Engineering: Principles and Applications* by Allan R. Hambley, Chapter 6.

২৭.
In a purely inductive AC circuit, the voltage across the inductor is 100V, and the inductive reactance is 25Ω. If the current is flowing in the circuit, what is the current through the inductor?
  1. 4A
  2. 5A
  3. 10A
  4. 2A
ব্যাখ্যা

Explanation:
In a purely inductive circuit, the relationship between voltage V), current (III), and inductive reactance (XL​) is given by Ohm's law for AC circuits:

V=I×XL
Where:

V=100V (voltage across the inductor),
XL=25Ω (inductive reactance),
I is the current through the inductor.
Now, rearrange the formula to solve for the current:

I=V / XL=100V / 25Ω=4A
Thus, the current through the inductor is 4A.

২৮.
The power factor of a circuit is the ratio of:
  1. Real power to apparent power
  2. Real power to reactive power
  3. Apparent power to real power
  4. Reactive power to apparent power
ব্যাখ্যা

Explanation:
The power factor (PF) of a circuit is the ratio of real power (P) to apparent power (S), and it indicates how effectively the current is being used to do useful work.The power factor is a number between 0 and 1, with 1 representing perfect efficiency (when voltage and current are in phase), and lower values indicating less efficient use of power due to phase differences (like inductive or capacitive loads).

খ) Real power to reactive power: This ratio doesn't represent the power factor. Reactive power is related to the energy stored and returned by inductive or capacitive elements and does not contribute to useful work.
গ) Apparent power to real power: This is the inverse of the power factor and does not represent the correct definition of power factor.
ঘ) Reactive power to apparent power: This ratio is related to the reactive power factor but is not the definition of the overall power factor.
Thus, the power factor is the ratio of real power to apparent power, or P/S

২৯.
What is the function of a commutator in a DC machine?
  1. To reverse the direction of current in the armature windings
  2. To increase the voltage in the machine
  3. To maintain constant speed
  4. To provide mechanical support to the rotor
ব্যাখ্যা

Explanation:
The commutator is used to reverse the current direction in the armature windings, ensuring that the torque generated in the DC machine is in a consistent direction.
Why not other options?
খ. The commutator does not directly increase the voltage.
গ. The speed of a DC machine is influenced by external factors, not the commutator.
ঘ. The commutator is not a mechanical support; its purpose is electrical.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩০.
What does the armature reaction cause in a DC generator?
  1. It increases the voltage output
  2. It distorts the magnetic field
  3. It improves efficiency
  4. It reduces the armature losses
ব্যাখ্যা

Explanation: Armature reaction distorts the magnetic field in the machine, leading to a reduction in generated voltage and causing uneven performance.
Why not other options?
ক). Armature reaction leads to a reduction in the voltage output.
গ). It actually reduces efficiency due to flux distortion.
ঘ). It increases losses in the armature due to distortion.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩১.
What is the working principle of a transformer?
  1. Faraday’s Law of Electromagnetic Induction
  2. Coulomb’s Law
  3. Ohm’s Law
  4. Lenz's Law
ব্যাখ্যা

Explanation:
Transformers work on the principle of Faraday’s law of electromagnetic induction, which states that a change in magnetic flux induces an EMF in the coil.
Why not other options?
খ. Coulomb’s Law relates to electrostatic force, not electromagnetic induction.
গ. Ohm’s Law applies to resistive circuits, not transformers.
ঘ. Lenz's Law is related to the direction of induced current, not directly to transformers.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩২.
What is the effect of increasing the number of poles in a synchronous machine?
  1. The speed of the machine decreases
  2. The torque produced increases
  3. The efficiency increases
  4. The power factor improves
ব্যাখ্যা

Explanation: In a synchronous machine, increasing the number of poles reduces the speed of the machine, as the speed is inversely proportional to the number of poles.
Why not other options?
খ. Torque is not directly affected by the number of poles.
গ. Efficiency is not influenced by the number of poles in a direct manner.
ঘ. Power factor is mainly affected by excitation, not the number of poles.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৩.
What is the purpose of the short-circuit test in a transformer?
  1. To measure the core losses
  2. To measure the copper losses
  3. To measure the open-circuit voltage
  4. To determine the efficiency
ব্যাখ্যা

Explanation: The short-circuit test is performed to measure the copper losses in the transformer by applying a reduced voltage and measuring the resulting current.
Why not other options?
ক) Core losses are measured during the no-load test, not the short-circuit test.
গ) The open-circuit voltage is measured in the no-load test.
ঘ) Efficiency is not directly determined by the short-circuit test.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৪.
What is the primary difference between a series-wound DC motor and a shunt-wound DC motor?
  1. Series-wound motors have higher efficiency
  2. Shunt-wound motors have high starting torque
  3. Series-wound motors are used in constant-speed applications
  4. Shunt-wound motors are used for speed control
ব্যাখ্যা

Explanation: Shunt-wound DC motors are typically used for speed control applications because their speed is relatively constant and can be easily varied by adjusting the field current.
Why not other options?
ক) Series-wound motors generally have low efficiency due to high armature losses.
খ) Shunt-wound motors do not provide high starting torque.
গ) Series-wound motors are used where high starting torque is required, not constant speed.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৫.
How does the rotor react when the load increases in an induction motor?
  1. The rotor speed increases
  2. The rotor current decreases
  3. The rotor speed decreases
  4. The rotor power factor improves
ব্যাখ্যা

Explanation: When the load on an induction motor increases, the slip increases, which causes the rotor speed to decrease slightly, bringing it closer to synchronous speed.
ক) The rotor speed increases: This is incorrect. In an induction motor, the rotor speed is always slightly less than the synchronous speed. When the load increases, the slip (the difference between synchronous speed and rotor speed) increases, causing the rotor speed to decrease, not increase.
খ) The rotor current decreases: This is incorrect. When the load increases, the rotor current increases, because more power is required to meet the increased load demand. The rotor current is directly related to the torque, and a higher load results in more current being induced in the rotor.
গ) The rotor speed decreases: This is correct. As the load on the motor increases, the motor requires more torque, and the slip increases, causing the rotor speed to decrease slightly. The rotor will slow down to maintain the necessary torque to handle the increased load.
ঘ) The rotor power factor improves: This is incorrect. As the load increases, the rotor power factor generally deteriorates because the induction motor operates less efficiently under high load conditions. The power factor improves when the motor operates closer to its full load but not necessarily because the load increases.

৩৬.
What is the effect of changing the supply frequency on the speed of a synchronous motor?
  1. The speed decreases
  2. The speed increases
  3. The speed remains constant
  4. The speed is inversely proportional to the supply frequency
ব্যাখ্যা

Explanation:
The speed of a synchronous motor is directly proportional to the supply frequency, so increasing the supply frequency will increase the speed.
Why not other options?
ক) The speed increases with the frequency.
খ) The speed does not remain constant as frequency changes.
ঘ) The speed is directly, not inversely, proportional to the supply frequency.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৭.
Which of the following is true about the efficiency of a transformer?
  1. Efficiency is highest at full load
  2. Efficiency is highest at no load
  3. Efficiency increases with frequency
  4. Efficiency decreases with increasing load
ব্যাখ্যা

Explanation:
The efficiency of a transformer is highest when it operates at full load because both copper and core losses are balanced at that point.
Why not other options?
খ) Efficiency is lowest at no load due to core losses.
গ) Frequency affects other parameters but not directly efficiency.
ঘ). Efficiency increases with load until it reaches maximum efficiency at full load.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৮.
In a transformer, what happens when the core material has high hysteresis loss?
  1. The efficiency of the transformer increases
  2. The transformer will produce higher output
  3. The transformer will experience more core loss
  4. The voltage regulation improves
ব্যাখ্যা

Explanation: 
Hysteresis loss is one of the components of core loss, along with eddy current loss. If the core material has high hysteresis loss, the transformer will experience more core loss, leading to reduced efficiency.
Why not other options?
ক) High hysteresis loss reduces efficiency.
খ) High hysteresis loss does not improve the transformer output.
ঘ). Voltage regulation is not improved by high hysteresis loss.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৩৯.
What happens to the efficiency of a DC motor as the load increases?
  1. Efficiency increases
  2. Efficiency remains constant
  3. Efficiency decreases
  4. The motor becomes unstable
ব্যাখ্যা

Explanation:
As the load on a DC motor increases, the motor operates closer to its rated efficiency point, causing efficiency to increase.
Why not other options?
খ) Efficiency increases with load, not stays constant.
গ). Efficiency does not decrease under normal load conditions.
ঘ) The motor remains stable unless overloaded.
Reference Book: *"Electrical Machines"* by P. S. Bimbhra

৪০.
What is the main purpose of a circuit breaker in a power system?
  1. To interrupt current during fault conditions
  2. To maintain a steady voltage
  3. To provide protection against overloads
  4. To store electrical energy
ব্যাখ্যা

Explanation:
The primary function of a circuit breaker is to interrupt the current when there is a fault (e.g., short circuit, overload) in the system. This prevents further damage to the system, such as overheating, fire, or equipment failure.
Why not other options?
খ). Voltage regulation is done by other equipment, not circuit breakers.
গ) Circuit breakers do not directly protect against overloads; overload protection is typically done by fuses or relays.
ঘ) Circuit breakers do not store energy, they interrupt it.
Reference Book: *"Power System Protection and Switchgear"* by B. Ravindranath

৪১.
What is a key advantage of using overhead transmission lines?
  1. They are cheaper than underground cables
  2. They have lower losses compared to underground cables
  3. They are more efficient for short distances
  4. They are less affected by environmental conditions
ব্যাখ্যা

Explanation: 

ক) They are cheaper than underground cables: This is correct. Overhead transmission lines are generally cheaper to install and maintain than underground cables. This is because underground cables require more complex and costly infrastructure, such as trenching, insulation, and protection from environmental factors.
খ) They have lower losses compared to underground cables: This is incorrect. In general, underground cables tend to have lower losses due to better insulation and less exposure to environmental factors, such as weather and physical damage. Overhead lines, on the other hand, are more prone to losses due to factors like air resistance and weather conditions.
গ) They are more efficient for short distances: This is incorrect. Overhead transmission lines are generally more suitable for longer distances, as they are cheaper and easier to maintain. For short distances, underground cables can sometimes be more efficient, especially in urban areas where space is limited.
ঘ) They are less affected by environmental conditions: This is incorrect. Overhead transmission lines are more susceptible to environmental conditions like wind, ice, lightning, and storms, which can lead to outages or physical damage. In contrast, underground cables are less affected by these external factors.

৪২.
In a generator, what is the function of the field winding?
  1. To supply mechanical energy
  2. To create a magnetic field
  3. To control the speed of the generator
  4. To convert mechanical energy to electrical energy
ব্যাখ্যা

Explanation: 

In a generator, the field winding plays a crucial role in generating the magnetic field that is essential for the conversion of mechanical energy into electrical energy. Let’s analyze the options:

ক) To supply mechanical energy: This is incorrect. The field winding does not supply mechanical energy. The mechanical energy needed for a generator comes from an external source, such as a turbine or engine, which drives the rotor.
খ) To create a magnetic field: This is correct. The primary function of the field winding in a generator is to create the magnetic field required for the operation of the generator. This magnetic field interacts with the armature windings (where the electric current is induced) to generate electricity.
গ) To control the speed of the generator: This is incorrect. The field winding does not control the speed of the generator. The speed of the generator is determined by the mechanical input (such as the speed of the turbine or engine driving the rotor).
ঘ) To convert mechanical energy to electrical energy: This is incorrect. While the generator as a whole converts mechanical energy to electrical energy, the field winding specifically creates the magnetic field needed for this conversion. The conversion itself occurs due to the interaction between the magnetic field and the rotating armature.

৪৩.
What does a synchronous generator primarily produce?
  1. DC output
  2. AC output with a constant frequency
  3. AC output with a variable frequency
  4. Variable voltage
ব্যাখ্যা

Explanation: 

A synchronous generator is designed to produce alternating current (AC) with a constant frequency. This is because the speed of the generator's rotor is synchronized with the frequency of the electrical supply, and the number of poles in the generator determines the relationship between the rotor speed and the output frequency.

Let's analyze the options:

ক) DC output: This is incorrect. A synchronous generator produces AC (alternating current), not DC (direct current). DC generators are used for producing DC output, but synchronous generators produce AC.
খ) AC output with a constant frequency: This is correct. A synchronous generator produces AC output, and the frequency is constant as long as the generator is running at a constant speed. The frequency of the output is determined by the speed of the rotor and the number of poles in the generator.
গ) AC output with a variable frequency: This is incorrect. A synchronous generator is designed to produce constant frequency AC. If the speed of the rotor changes, the frequency would change, but under normal operation, the generator maintains a constant speed and frequency.
ঘ) Variable voltage: This is incorrect. While the voltage output of a synchronous generator can vary depending on the load and excitation, it does not inherently produce variable voltage under normal operating conditions. The generator’s voltage is typically controlled by adjusting the excitation of the field winding.

৪৪.
What is the effect of increasing the excitation of a synchronous motor?
  1. It increases the speed
  2. It decreases the power factor
  3. It improves the power factor
  4. It reduces the efficiency
ব্যাখ্যা

Explanation: 

The excitation of a synchronous motor refers to the current supplied to the field windings that create the magnetic field in the rotor. The level of excitation affects various characteristics of the motor, particularly its power factor and operating conditions.

Let's analyze the options:
ক) It increases the speed: This is incorrect. The speed of a synchronous motor is constant and is determined by the supply frequency and the number of poles in the motor. Changing the excitation does not affect the speed; it affects the motor's power factor and reactive power.
খ) It decreases the power factor: This is incorrect. Increasing the excitation of a synchronous motor actually improves the power factor, especially if the motor was initially operating at a lagging power factor. Over-excitation (increasing excitation) causes the motor to act more like a capacitor, leading to a leading power factor.
গ) It improves the power factor: This is correct. Increasing the excitation of a synchronous motor improves the power factor. When the motor is over-excited (increased excitation), it generates more reactive power, which can compensate for lagging power factors in the system, thus improving the overall power factor.
ঘ) It reduces the efficiency: This is incorrect. Increasing excitation does not directly reduce the efficiency. However, excessive excitation could lead to higher losses due to over-excitation, but typically, increasing excitation within normal limits improves the power factor and does not reduce efficiency.

৪৫.
What happens in a three-phase fault in a power system?
  1. Only one phase is affected
  2. The system becomes unstable
  3. The current increases in the faulty phase
  4. All three phases are affected equally
ব্যাখ্যা

Explanation: 
In a three-phase fault in a power system, a fault occurs when all three phases of the system are simultaneously involved, typically causing a short circuit between the phases. All three phases are affected simultaneously, not just one phase. A fault that affects only one phase is a single-phase fault, not a three-phase fault.
Why not other options?
ক) A three-phase fault affects all three phases.
খ)  The system does not necessarily become unstable immediately but will require protection to clear the fault.
গ) The current increases in all phases during a fault, not just one.
Reference Book: *"Power System Protection and Switchgear"* by B. Ravindranath

৪৬.
What is the purpose of using a STATCOM (Static Synchronous Compensator)?
  1. To improve the system’s power factor
  2. To regulate the system voltage
  3. To increase the system’s stability
  4. All of the above
ব্যাখ্যা

A STATCOM (Static Synchronous Compensator) is a device used in power systems to improve the quality of power, enhance system stability, and regulate various electrical parameters. Let's break down the options:

ক) To improve the system’s power factor: This is correct. One of the main functions of a STATCOM is to provide reactive power compensation. By injecting or absorbing reactive power, it helps improve the power factor of the system, particularly in cases where there are fluctuations in reactive power demand.
খ) To regulate the system voltage: This is correct. STATCOMs are also used to regulate voltage in the system. They can provide fast and dynamic voltage support by adjusting the amount of reactive power in response to changes in the system, helping maintain a stable voltage profile.
গ) To increase the system’s stability: This is correct. STATCOMs improve the stability of the power system, especially in situations where there are voltage instability problems or during disturbances. They help stabilize the system by providing or absorbing reactive power in real-time, which improves the system's dynamic response.
ঘ) All of the above: This is correct. STATCOMs are designed to improve power factor, regulate system voltage, and increase system stability. All of these functions are essential for the efficient and reliable operation of the power grid, particularly in dynamic and fluctuating load conditions.

৪৭.
What is the primary cause of voltage sag during a fault condition?
  1. Increased fault current
  2. Decreased system impedance
  3. Reduction in the reactive power supply
  4. Short-circuit fault
ব্যাখ্যা

Explanation:
A short-circuit fault leads to a dramatic decrease in voltage due to the high current flowing through the fault path.
Short-circuit faults cause a dramatic drop in voltage because they create a low-resistance path that allows high fault currents, pulling down the voltage across the system.
Other options, such as increased fault current and reduction in reactive power supply, are related to the fault, but the short-circuit fault itself is the direct cause of the voltage sag.

৪৮.
What is the advantage of using HVDC transmission over AC transmission for long distances?
  1. Reduce efficiency
  2. Lower cost
  3. Reduced power losses
  4. No need for transformers
ব্যাখ্যা

Explanation:
HVDC transmission increases efficiency for long-distance power transmission. HVDC systems have lower line losses over long distances, especially compared to AC transmission systems, which suffer from reactive power losses.
Why not other options?
ক) HVDC is more efficient, but not necessarily higher in efficiency than AC for short distances.
খ) HVDC systems are more expensive to install than AC systems.
ঘ) HVDC still requires converters and transformers at both ends.
Reference Book: *"High Voltage Direct Current (HVDC) Transmission Systems"* by K. R. Padiyar

৪৯.
What is the primary role of a current-limiting reactor in a power system?
  1. To improve voltage stability
  2. To limit fault current
  3. To protect transformers
  4. To filter harmonic frequencies
ব্যাখ্যা

Explanation: A current-limiting reactor is used to limit the magnitude of fault current during a fault condition, preventing damage to the system.
Why not other options?
ক) Voltage stability is regulated by other devices such as voltage regulators.
গ) Current-limiting reactors protect circuits from faults, not transformers.
ঘ) Harmonic filtering is done by filters, not current-limiting reactors.
Reference Book: *"Power System Protection and Switchgear"* by B. Ravindranath

৫০.
What is the purpose of using impedance relays in power systems?
  1. To measure the fault resistance
  2. To detect faults based on impedance changes
  3. To regulate voltage
  4. To monitor the load flow
ব্যাখ্যা

Explanation: 

The purpose of using impedance relays in power systems is to detect faults based on impedance changes. Let’s break down the options:

ক) To measure the fault resistance: This is incorrect. While impedance relays are related to faults, their purpose is not specifically to measure fault resistance. Instead, they detect changes in impedance caused by fault conditions (such as short circuits or open circuits).
খ) To detect faults based on impedance changes: This is correct. Impedance relays detect faults in the power system by measuring the impedance between the relay and the fault location. When a fault occurs, the impedance of the system changes, and the relay responds by detecting these changes, which helps identify the presence of a fault.
গ) To regulate voltage: This is incorrect. Impedance relays do not regulate voltage. Voltage regulation is typically handled by other devices such as voltage regulators, transformers, or capacitor banks.
ঘ) To monitor the load flow: This is incorrect. Impedance relays do not monitor load flow. Load flow analysis is typically done with other tools or devices, such as load flow controllers or SCADA systems, which provide real-time monitoring of power flow.

৫১.
Which type of circuit breaker uses sulfur hexafluoride (SF6) gas for arc quenching?
  1. Air Circuit Breaker (ACB)
  2. Oil Circuit Breaker (OCB)
  3. Vacuum Circuit Breaker (VCB)
  4. SF6 Circuit Breaker
ব্যাখ্যা

Explanation:
SF6 (sulfur hexafluoride) circuit breakers use SF6 gas as the quenching medium to extinguish the arc formed when the contacts are separated. This gas has excellent dielectric properties, making it effective at preventing electrical arcing and allowing for reliable operation.

৫২.
Which transmission voltage is generally used in Bangladesh for long distance transmission?
  1. 11KV
  2. 33 KV
  3. 132 KV
  4. 400 KV
ব্যাখ্যা

Explanation:
In Bangladesh, 132 kV is commonly used for long-distance transmission of electricity. High voltage levels like 132 kV are used for efficient transmission over long distances because they reduce the current, which in turn reduces power losses.

11 kV and 33 kV are generally used for local distribution of electricity.
400 kV is used in some countries for very high-voltage transmission lines, but in Bangladesh, 132 kV is more typical for long-distance transmission.

৫৩.
The corona loss in a transmission line is reduced by:
  1. Increasing conductor size
  2. Reducing spacing between conductors
  3. Using rough surface conductors
  4. Increasing line voltage
ব্যাখ্যা

Explanation:
Corona loss occurs when the voltage on the transmission line is high enough to ionize the surrounding air, causing electrical discharge (corona discharge), which leads to power losses. The factors that affect corona loss include the line voltage, conductor size, and spacing between conductors.

Increasing conductor size reduces corona loss because it decreases the electric field intensity around the conductors. Larger conductors have a larger surface area, which reduces the chance of ionizing the air around them, thus reducing corona discharge.
Now, let's consider the other options:

খ) Reducing spacing between conductors: This increases the electric field strength between conductors, which can lead to a higher likelihood of corona discharge, thus increasing corona loss.
গ) Using rough surface conductors: Rough surfaces increase the local electric field, making it more likely to ionize the air around the conductor, which increases corona loss rather than reducing it.
ঘ) Increasing line voltage: Increasing the voltage also increases the electric field strength around the conductor, which could increase corona loss. Therefore, it is not a method to reduce it.

৫৪.
Which of the following is the most economical power factor?
  1. 0.707
  2. 0.8 lag
  3. 0.9 lag
  4. Unity (1)
ব্যাখ্যা

Explanation: Unity power factor means all supplied power is real power, making it the most economical condition

৫৫.
The Ferranti effect is prominent in:
  1. Long transmission lines at light load
  2. Short transmission lines at heavy load
  3. Short transmission lines at light load
  4. None of the above
ব্যাখ্যা

Explanation:
The Ferranti effect is a phenomenon that occurs in long transmission lines operating at light loads (or no load). It is characterized by an increase in the voltage at the receiving end of the transmission line compared to the sending end. This effect is primarily caused by the capacitive reactance of long transmission lines, which can cause a voltage rise under light load conditions.

Here’s why the other options are incorrect:

B) Short transmission lines at heavy load:
Short transmission lines don't exhibit the Ferranti effect because they have less capacitance and, hence, less reactive power. The voltage rise due to capacitive effects is more prominent in long lines.
C) Short transmission lines at light load:
Short transmission lines typically don't experience the Ferranti effect, even at light load, because the capacitive reactance is relatively small compared to long lines. Ferranti effect is mainly seen in long lines due to their higher capacitive reactance.
D) None of the above:
This is incorrect because the Ferranti effect is most prominent in long transmission lines at light load, which is option A.

৫৬.
The unit of electrical energy consumed is:
  1. Watt
  2. Watt-Hour
  3. Kilowatt-hour
  4. Joule
ব্যাখ্যা

Explanation: Electrical energy consumed by consumers is measured in kWh (1 kWh = 1000 watt × 3600 seconds = 3.6 × 10⁶ J).

৫৭.
The diversity factor of a power plant is always:
  1. Less than 1
  2. Equal to 1
  3. Greater than 1
  4. Infinity 
ব্যাখ্যা

Explanation:
The diversity factor of a power plant is the ratio of the sum of individual maximum demands of the consumers to the maximum demand of the power plant. It measures how much the demand from different consumers varies over time.

A diversity factor greater than 1 indicates that not all consumers require their maximum demand at the same time. In other words, the total demand is less than the sum of individual peak demands, which results in a higher diversity factor.
In most power systems, the diversity factor is always greater than 1 because it reflects the fact that different consumers' demands are not simultaneous.
Why other options are incorrect:

ক) Less than 1:
A diversity factor less than 1 is not possible because it would imply that the sum of individual maximum demands is less than the total demand, which contradicts the definition.
খ) Equal to 1:
A diversity factor equal to 1 means that the maximum demand is the sum of individual maximum demands, implying that all consumers' maximum demands occur at the same time. This is highly unlikely in real power systems, so the diversity factor is generally greater than 1.
ঘ) Infinity:
An infinite diversity factor would imply that the total demand is infinitely less than the sum of individual maximum demands, which is unrealistic in practical systems.

৫৮.
In a 3-phase balanced system, the neutral current is:
  1. Maximum
  2. Zero
  3. Half of line current
  4. Depends on load
ব্যাখ্যা

Explanation:
In a 3-phase balanced system, the neutral current is zero under balanced load conditions. This is because in a balanced system, the three-phase currents are equal in magnitude and 120 degrees out of phase with each other.

The sum of the three-phase currents at any instant is always zero, which means there is no current flowing through the neutral conductor. In other words, the three-phase system is "balanced," and there is no need for current to flow through the neutral.

Why the other options are incorrect:
ক) Maximum:
The neutral current cannot be maximum in a balanced 3-phase system. It would only occur if the system is unbalanced, in which case the sum of the three-phase currents would not cancel each other out, and some current would flow through the neutral.
গ) Half of line current:
This is not true in a balanced system. The neutral current would be zero, not a fraction of the line current.
ঘ) Depends on load:
In a balanced system, the neutral current does not depend on the load, as long as the system remains balanced. If the system is unbalanced, the neutral current could depend on the load imbalance.

৫৯.
Which protection is provided on transmission lines for lightning?
  1. Circuit breaker
  2. Surge diverter (Lightning arrester)
  3. Isolator
  4. Earth wire
ব্যাখ্যা

Explanation:
A surge diverter or lightning arrester is used to protect transmission lines from lightning strikes. It is designed to divert the excess voltage caused by lightning or other transient surges to the ground, thereby preventing damage to the transmission equipment.

Here’s why the other options are not correct for lightning protection:

ক) Circuit breaker:
A circuit breaker is used to interrupt the power flow in case of a fault (e.g., short circuit) but is not specifically designed to handle lightning or transient surges. It would open the circuit to prevent further damage, but it doesn't protect against the surge from lightning.
গ) Isolator:
An isolator is used to isolate a part of the system for maintenance or repair, but it does not protect against lightning or surge currents. It simply disconnects the circuit when required.
ঘ) Earth wire:
While an earth wire (also called a grounding wire) is used for safety to direct fault currents to the ground, it is not the primary protection against lightning strikes. It helps to safely discharge faults but is not designed to specifically divert lightning surges like a surge diverter does.

৬০.
If the phase sequence of orginal system is abc, then the phase sequence of negative sequence current will be?
  1. cab
  2. acb
  3. bac
  4. none of the above
ব্যাখ্যা

Explanation: 
In a three-phase system, the phase sequence of the negative sequence current is the reverse of the phase sequence of the original system. Given that the phase sequence of the original system is abc, the phase sequence of the negative sequence current will be the reverse, which is acb

৬১.
What is the characteristic equation of a system?
  1. The equation that determines system stability
  2. The equation for the system's output
  3. The equation that defines the transfer function
  4. The equation derived from the system's poles and zeros
ব্যাখ্যা

Explanation:
The characteristic equation helps determine the system's poles, which in turn affect system stability.
      খ) Output is determined by the transfer function.
      গ) Transfer function is a ratio, not an equation.
      ঘ) Poles and zeros are found from the characteristic equation, not the other way around.

৬২.
What is the main advantage of using a state-space representation in control systems?
  1. It provides a simple transfer function for analysis
  2. It can model multivariable systems
  3. It only works for linear systems
  4. It reduces computational complexity
ব্যাখ্যা

Explanation:
The state-space representation is a powerful method in control systems that has several key advantages, and one of the main benefits is its ability to handle multivariable systems. These are systems with multiple inputs and outputs, which are common in real-world applications.

Let’s go over why the other options aren’t correct:

ক) It provides a simple transfer function for analysis:

This is not true for state-space representation. While transfer functions are useful for single-input single-output (SISO) systems, state-space representation is generally more flexible, especially for multivariable systems. It doesn’t necessarily give you a "simple" transfer function but instead provides a set of equations that describe the system's dynamics.

গ) It only works for linear systems:

While state-space representation is typically used for linear systems, it can also be extended to nonlinear systems (though it becomes more complex). So, it's not restricted only to linear systems.
ঘ) It reduces computational complexity:

This is not the main advantage. In fact, state-space representation can be computationally more intensive for certain systems, especially when compared to transfer function methods for simple SISO systems. The advantage lies more in its ability to handle complex, multivariable systems and time-domain analysis.

৬৩.
What is the purpose of a compensator in control systems?
  1. To adjust the system gain
  2. To modify the system dynamics for desired performance
  3. To eliminate system poles
  4. To reduce feedback signal noise
ব্যাখ্যা

Explanation:
A compensator is used in control systems to modify the dynamics of the system to achieve desired performance characteristics such as improved stability, faster response, reduced overshoot, or better accuracy. Essentially, it compensates for undesirable behavior in the system and helps in tuning the system to meet the specifications.

Let’s go through why the other options are not correct:

ক) To adjust the system gain:
While compensators may affect the system gain indirectly, their primary function is not just to adjust gain. A compensator typically alters the dynamics (such as phase or frequency response), not just the gain. Adjusting gain is more of a direct controller design task.
গ) To eliminate system poles:
A compensator does not eliminate poles but can move them to more favorable locations in the complex plane to improve stability and response. The compensator adjusts the system's behavior by adding poles or zeros, not necessarily by eliminating them.
ঘ) To reduce feedback signal noise:
While a compensator might affect the system's sensitivity to noise, reducing feedback signal noise is not its primary purpose. The compensator's primary purpose is to improve the system’s dynamic performance and stability.

৬৪.
Which of the following is a disadvantage of using an integral controller?
  1. It introduces steady-state error
  2. It can cause windup
  3. It improves system stability
  4. It reduces system response time
ব্যাখ্যা

Explanation:
An integral controller is commonly used in control systems to eliminate steady-state error by integrating the error over time. However, it comes with the disadvantage of integral windup.

Integral windup occurs when the integral action accumulates a large error over time, especially when the system is in saturation (e.g., when the output is at its maximum or minimum limit). This can cause the controller to become overly aggressive, leading to large overshoot and delayed settling time, even after the error has been corrected.

Let's break down the other options:
খ) It introduces steady-state error:
This is not true. The purpose of the integral controller is to eliminate steady-state error. By integrating the error over time, it continuously adjusts the output until the error is zero in the steady-state.
গ) It improves system stability:
While an integral controller helps eliminate steady-state error, it can reduce system stability. The integration process can introduce phase lag, which may lead to slower responses or even instability if not properly tuned.
ঘ) It reduces system response time:
An integral controller does not necessarily reduce the response time. In fact, it can increase the response time because it adjusts the system output gradually over time to eliminate error, which might slow down the system's initial response.

৬৫.
What is the main function of a steam turbine in a thermal power plant?
  1. To generate electricity
  2. To increase the temperature of water
  3. To condense steam
  4. To transfer mechanical energy to the generator
ব্যাখ্যা

Explanation:
In a thermal power plant, the steam turbine converts the thermal energy from steam into mechanical energy (rotational motion). This mechanical energy is then used to drive the generator, which produces electricity.

Here’s a quick breakdown of why the other options are incorrect:

ক) To generate electricity: While the steam turbine plays a crucial role in generating electricity, it doesn’t directly generate the electricity. It generates mechanical energy, which is then used by the generator to produce electricity.
খ) To increase the temperature of water: The steam turbine doesn't increase the temperature of water. The boiler is responsible for heating water to generate steam.
গ) To condense steam: The condenser is responsible for condensing steam back into water, not the turbine.

৬৬.
What does a load curve represent in a power system?
  1. The maximum capacity of a plant
  2. The variation of load over time
  3. The fuel consumption rate of the plant
  4. The efficiency of the plant
ব্যাখ্যা

Explanation:
A load curve in a power system represents the variation of electric load (demand for electricity) over a specific period, typically shown in terms of hours, days, or seasons. It provides valuable information about the fluctuations in power demand, helping utilities manage and plan for generation and distribution.

Why the other options are incorrect:
ক) The maximum capacity of a plant: A load curve does not show the maximum capacity of a plant, but rather the variation in demand over time.
গ) The fuel consumption rate of the plant: While fuel consumption is related to load, a load curve does not directly show fuel consumption. It represents the electrical demand or load.
ঘ) The efficiency of the plant: The load curve does not directly represent plant efficiency; instead, it shows the changes in load (demand) over time.

৬৭.
What is the primary benefit of using a combined cycle power plant?
  1. Improved efficiency
  2. Reduced fuel consumption
  3. Lower installation cost
  4. Simplified operation
ব্যাখ্যা

Explanation:
A combined cycle power plant combines two power generation cycles — a gas turbine cycle and a steam turbine cycle. The waste heat from the gas turbine is used to generate steam, which drives a steam turbine, thus utilizing energy that would otherwise be wasted. This results in higher overall efficiency compared to single-cycle plants.

Why the other options are incorrect:
খ) Reduced fuel consumption: While the plant is more efficient, the fuel consumption per unit of electricity generated is typically lower, but this isn't the primary benefit. The efficiency improvement is the main benefit.
গ) Lower installation cost: Combined cycle plants are more complex and tend to have a higher initial installation cost compared to single-cycle plants due to additional equipment (steam turbine, heat recovery systems, etc.).
ঘ) Simplified operation: Combined cycle plants are more complex to operate due to the combination of two cycles (gas and steam turbines), so the operation is not necessarily simpler

৬৮.
Which renewable energy technology converts sunlight directly into electricity?
  1. Wind Turbine
  2. Photovoltaic Cell
  3. Fuel Cell
  4. Tidal Energy
ব্যাখ্যা

Explanation: Photovoltaic cells directly convert sunlight into electricity through the photovoltaic effect.
Why not other options?
ক) Wind turbines convert wind energy, not sunlight.
গ) Fuel cells convert chemical energy, not sunlight.
ঘ) Tidal energy is derived from water, not sunlight.
Reference Book: *"Renewable Energy: Power for a Sustainable Future"* by Godfrey Boyle

৬৯.
What is the primary factor that determines the location of a thermal power plant?
  1. Availability of fuel
  2. Availability of water
  3. Proximity to consumers
  4. Environmental conditions
ব্যাখ্যা

Explanation:
The primary factor that determines the location of a thermal power plant is the availability of fuel (such as coal, natural gas, or oil). Thermal power plants rely on the combustion of these fuels to generate heat and produce electricity. Therefore, being close to fuel sources reduces transportation costs and ensures a steady supply.

Why the other options are less important:
খ) Availability of water: While water is needed for cooling in thermal power plants, it is usually a secondary consideration. Many plants are designed to use water efficiently or may use cooling towers to minimize water usage. However, fuel availability is more critical.
গ) Proximity to consumers: While being close to consumers is beneficial for reducing transmission losses, fuel availability is typically a more decisive factor in the location of thermal power plants.
ঘ) Environmental conditions: Although environmental regulations and conditions (like wind or pollution control) are considered, they do not usually outweigh the importance of proximity to fuel sources for thermal plants.

৭০.
What is the formula used to estimate the heat rate of a power plant?
  1. Heat rate = Energy Output / Fuel Consumption
  2. Heat rate = Fuel Consumption / Energy Output
  3. Heat rate = Efficiency / Power Factor
  4. Heat rate = Fuel Input / Electric Power Output
ব্যাখ্যা

Explanation: Heat rate is calculated as the amount of fuel energy required to produce one unit of electricity.
Why not other options?
ক) This formula is reversed.
গ) Efficiency is irrelevant in calculating heat rate.
ঘ) The formula is incorrect.
Reference Book: *"Power Plant Engineering"* by P. K. Nag

৭১.
Which factor is considered while designing a hydropower plant?
  1. Availability of sunlight
  2. Proximity to wind sources
  3. Water flow and head
  4. Amount of biomass available
ব্যাখ্যা

Explanation:
When designing a hydropower plant, the two critical factors are:

Water flow: The amount of water passing through the system, usually measured in cubic meters per second. A higher flow allows more energy to be harnessed.
Head: The vertical distance the water falls. The greater the head, the more potential energy is available to convert into electricity.
These two factors determine the amount of potential energy that can be converted into electricity in a hydropower system.

Why the other options are incorrect:
ক) Availability of sunlight: This is relevant for solar power plants, not for hydropower plants.
খ) Proximity to wind sources: This is relevant for wind power plants, not hydropower plants.
ঘ) Amount of biomass available: Biomass is relevant for biomass power plants, not hydropower.

৭২.
What does the load curve represent in power plant performance?
  1. The maximum capacity of a plant
  2. The variation of load over time
  3. The fuel consumption rate of the plant
  4. The efficiency of the plant
ব্যাখ্যা

Explanation:
A load curve in power plant performance represents how the electric load (the demand for electricity) changes over a specified period, such as a day, week, or year. It shows the variation of the electrical demand, helping utilities understand peak loads, base loads, and load fluctuations. This information is crucial for optimizing plant operation, load forecasting, and planning for capacity needs.

Why the other options are incorrect:
ক) The maximum capacity of a plant: The load curve does not directly represent the maximum capacity of the plant. The maximum capacity refers to the highest output the plant can generate, while the load curve shows how the demand changes over time.
গ) The fuel consumption rate of the plant: While fuel consumption can be influenced by the load, the load curve itself does not represent the fuel consumption rate. The fuel consumption rate is related to the amount of electricity being generated.
ঘ) The efficiency of the plant: The efficiency of the plant refers to how effectively it converts fuel into electricity, but the load curve does not directly show this.

৭৩.
What is the primary reason for using a hybrid power system?
  1. To decrease installation cost
  2. To ensure power availability during low generation periods
  3. To increase the overall efficiency
  4. To simplify system maintenance
ব্যাখ্যা

Explanation:
A hybrid power system combines two or more different types of energy sources, such as solar, wind, diesel generators, or hydropower, to provide a more reliable and consistent power supply. The primary reason for using a hybrid system is to ensure that there is power availability even during low generation periods (e.g., cloudy days for solar or calm days for wind). This ensures a continuous supply of power when one energy source is not producing enough electricity.

Why the other options are incorrect:
ক) To decrease installation cost: Hybrid systems typically have higher initial installation costs due to the integration of multiple energy sources and their associated equipment. While they might reduce operational costs over time, the installation cost is not their primary advantage.
গ) To increase the overall efficiency: While hybrid systems can improve reliability, they do not necessarily lead to an increase in efficiency. The focus is more on ensuring power availability, especially during periods of low generation from certain sources.
ঘ) To simplify system maintenance: Hybrid systems can actually increase the complexity of system maintenance because they involve multiple types of equipment and technologies, which require different maintenance procedures.

৭৪.
What is the function of moderators in nuclear reactors?
  1. To increase the chain reaction rate
  2. To slow down neutrons to sustain the chain reaction
  3. To cool the reactor core
  4. To control the electrical output of the reactor
ব্যাখ্যা

Explanation:
In a nuclear reactor, moderators are materials used to slow down fast neutrons produced during fission. Slowing down these neutrons makes them more likely to interact with other nuclear fuel atoms and sustain the chain reaction. The slower neutrons (thermal neutrons) are more efficient at causing further fission reactions, which is crucial for maintaining a steady power output in the reactor.

Why the other options are incorrect:
ক) To increase the chain reaction rate: While moderators help sustain the chain reaction, they do not directly increase the rate of the chain reaction. They just slow down neutrons to a speed that makes the reaction more likely to continue.
গ) To cool the reactor core: The function of cooling the reactor core is carried out by the coolant, not the moderator. The coolant absorbs the heat generated by fission and transfers it away from the core.
ঘ) To control the electrical output of the reactor: The electrical output of the reactor is controlled by adjusting the control rods, which absorb neutrons and regulate the chain reaction, not by the moderators.

৭৫.
What is the basic principle behind amplitude modulation?
  1. Varying the amplitude of the carrier with respect to the message signal
  2. Varying the frequency of the carrier
  3. Varying the phase of the carrier
  4. Modulating the frequency of the message signal
ব্যাখ্যা

Explanation:
Amplitude Modulation (AM) works by varying the amplitude of the carrier signal in proportion to the instantaneous amplitude of the message signal (or baseband signal). The frequency and phase of the carrier remain constant, while its amplitude changes to carry the information.

In AM, the carrier wave is multiplied by the message signal, resulting in a modulated signal with varying amplitude. This allows the transmission of the message signal (e.g., audio or data) over a communication channel.

Why the other options are incorrect:
খ) Varying the frequency of the carrier: This describes Frequency Modulation (FM), not amplitude modulation.
গ) Varying the phase of the carrier: This describes Phase Modulation (PM), not amplitude modulation.
ঘ) Modulating the frequency of the message signal: This is not a characteristic of AM. Instead, it describes a type of modulation like Frequency Modulation (FM), where the message signal affects the carrier's frequency.

৭৬.
Which of the following types of noise is most commonly associated with communication systems?
  1. Thermal Noise
  2. Shot Noise
  3. Impulse Noise
  4. Flicker Noise
ব্যাখ্যা

Explanation:
Thermal Noise (also known as Johnson-Nyquist noise) is the most common type of noise in communication systems. It arises due to the random motion of electrons in conductors and is present in all electronic components. It is typically present in communication systems because of the temperature of the conductors, and its power is proportional to the temperature and the bandwidth of the system.

Why the other options are incorrect:
খ) Shot Noise: Shot noise is related to the discrete nature of current flow in electronic devices, especially semiconductor devices. It becomes significant in systems with very low currents or small signals, but it's not as universally present as thermal noise.
গ) Impulse Noise: Impulse noise consists of sudden and short bursts of energy, such as those caused by lightning or switching events. While it can disrupt communication, it’s not as common or persistent as thermal noise.
ঘ) Flicker Noise: Flicker noise, or 1/f noise, is usually seen in low-frequency systems and is more prominent in certain electronic components like transistors. It is not as prevalent across all communication systems compared to thermal noise.

৭৭.
What is the bandwidth requirement for an ideal AM signal?
  1. Twice the message bandwidth
  2. The same as the message bandwidth
  3. Half the message bandwidth
  4. Infinite
ব্যাখ্যা

Explanation:
For an Amplitude Modulation (AM) signal, the bandwidth requirement is twice the message bandwidth.

This is because in AM, the carrier signal is modulated by the message signal, and the modulated signal contains two symmetrical sidebands on either side of the carrier frequency. These sidebands carry the same information as the message signal. So, if the message signal has a bandwidth of B Hz, the AM signal will have a bandwidth of 2B Hz, including the carrier and both sidebands.

Why the other options are incorrect:
খ) The same as the message bandwidth: This is true for single-sideband modulation (SSB), but not for AM. In AM, the bandwidth is twice the message bandwidth.
গ) Half the message bandwidth: This is not correct. AM bandwidth is twice the message bandwidth, not half.
ঘ) Infinite: This would be the case for a perfectly modulated signal in some theoretical scenarios or in cases like frequency modulation (FM) with an infinite number of sidebands. However, AM has a finite bandwidth, which is twice the message bandwidth.

৭৮.
What is the main advantage of using frequency modulation (FM) over amplitude modulation (AM)?
  1. FM is more resistant to noise
  2. FM has a higher bandwidth requirement
  3. FM is easier to implement
  4. FM requires less power
ব্যাখ্যা

Explanation:
Frequency Modulation (FM) offers a significant advantage over Amplitude Modulation (AM) in terms of resistance to noise. In FM, information is encoded in the frequency variation of the carrier, not in the amplitude. Since noise typically affects the amplitude of a signal, FM signals are more robust against noise, such as static or interference from other signals.

Why the other options are incorrect:
খ) FM has a higher bandwidth requirement: It's true that FM typically requires a larger bandwidth than AM, but this is not its main advantage. The key advantage of FM is its resistance to noise, not its bandwidth.
গ) FM is easier to implement: FM is generally more complex to implement than AM. It requires more sophisticated modulation and demodulation equipment, making it more technically challenging and costlier in some cases.
ঘ) FM requires less power: FM signals typically require more power than AM signals for the same coverage area because FM signals have a larger bandwidth and require higher transmitter power to maintain signal quality.

৭৯.
What is the primary characteristic of phase modulation (PM)?
  1. Modulating the amplitude of the carrier
  2. Modulating the phase of the carrier
  3. Modulating the frequency of the message signal
  4. Modulating the signal power
ব্যাখ্যা

Explanation:
Phase Modulation (PM) involves varying the phase of the carrier signal in accordance with the amplitude of the message signal. The frequency and amplitude of the carrier remain constant, but the phase is altered based on the information being transmitted. This is the defining characteristic of Phase Modulation.

Why the other options are incorrect:
ক) Modulating the amplitude of the carrier: This is the characteristic of Amplitude Modulation (AM), not phase modulation.
গ) Modulating the frequency of the message signal: This describes Frequency Modulation (FM), where the frequency of the carrier is varied in accordance with the message signal, not the phase.
ঘ) Modulating the signal power: This is not the defining feature of PM. In phase modulation, the focus is on the phase of the carrier, not on the power of the signal.

৮০.
What is the primary purpose of the AGC (Automatic Gain Control) circuit in a communication system?
  1. To filter out noise
  2. To adjust the signal amplitude
  3. To change the frequency of the signal
  4. To modulate the signal
ব্যাখ্যা

Explanation:
The primary purpose of the Automatic Gain Control (AGC) circuit in a communication system is to adjust the signal amplitude automatically to maintain a consistent output level, despite variations in the input signal strength. AGC ensures that the signal's amplitude stays within a certain range, which helps improve signal quality and prevent distortion in communication systems, especially when the signal strength varies due to environmental factors.

Why the other options are incorrect:
ক) To filter out noise: AGC does not directly filter out noise. While maintaining a consistent signal level might help improve the signal-to-noise ratio, its main role is to adjust the signal's amplitude, not to filter noise.
গ) To change the frequency of the signal: AGC does not change the frequency of the signal. It only adjusts the amplitude of the signal to keep it within an optimal range.
ঘ) To modulate the signal: AGC does not modulate the signal. Modulation involves varying the carrier signal to transmit information, while AGC deals with controlling the amplitude of the signal.

৮১.
In digital communication, which modulation technique is used for binary data transmission?
  1. Amplitude Modulation
  2. Frequency Modulation
  3. Phase Shift Keying
  4. Pulse Code Modulation
ব্যাখ্যা

Explanation:
In digital communication, Phase Shift Keying (PSK) is commonly used for binary data transmission. In PSK, the phase of the carrier signal is varied according to the binary data. For example, in Binary Phase Shift Keying (BPSK), one phase represents a binary "0" and another phase represents a binary "1".

Why the other options are incorrect:
ক) Amplitude Modulation: AM is primarily used in analog communication, not for binary data transmission. In digital systems, the signal is often either on or off, making amplitude modulation less suitable for binary data.
খ) Frequency Modulation: FM is used for analog communication and is not as commonly used in binary data transmission. It is more suitable for continuous signals or analog transmission.
ঘ) Pulse Code Modulation (PCM): PCM is a technique used for converting analog signals into digital signals, but it is not a modulation technique used directly for binary data transmission like PSK.

৮২.
What is the function of a demodulator in an FM receiver?
  1. To convert the frequency-modulated signal to a baseband signal
  2. To convert the signal to amplitude modulation
  3. To convert digital data into analog signal
  4. To increase the signal power
ব্যাখ্যা

Explanation:
In an FM (Frequency Modulation) receiver, the demodulator extracts the original baseband signal (such as audio or data) from the frequency-modulated signal. The FM signal carries information in the form of frequency variations, and the demodulator works to convert those frequency changes back into the original message signal.

Why the other options are incorrect:
খ) To convert the signal to amplitude modulation: This is not the function of the demodulator in an FM receiver. FM is based on frequency changes, not amplitude, so the demodulator does not convert FM to AM.
গ) To convert digital data into analog signal: This refers to a digital-to-analog converter (DAC), which is not the function of an FM demodulator. The FM demodulator works with analog FM signals, not digital data.
ঘ) To increase the signal power: The task of increasing signal power is done by an amplifier, not the demodulator. The demodulator's job is to recover the information, not amplify it.

৮৩.
Which multiplexing technique is used for dividing a communication channel into multiple time slots?
  1. Frequency Division Multiplexing
  2. Time Division Multiplexing
  3. Code Division Multiplexing
  4. Wavelength Division Multiplexing
ব্যাখ্যা

Explanation:
Time Division Multiplexing (TDM) is a technique used to divide a communication channel into multiple time slots. Each time slot is assigned to a different signal or data stream, and these signals are transmitted in rapid succession, one after another, during their designated time slots. This allows multiple signals to share the same channel without interference.

Why the other options are incorrect:
ক) Frequency Division Multiplexing (FDM): In FDM, the communication channel is divided into multiple frequency bands, with each band carrying a different signal. It is not based on time slots.
গ) Code Division Multiplexing (CDM): CDM allows multiple signals to be transmitted simultaneously over the same frequency band by assigning each signal a unique code. It is based on coding rather than time slots.
ঘ) Wavelength Division Multiplexing (WDM): WDM is used in optical fiber communications to divide the optical spectrum into different wavelengths (or channels), each carrying a separate signal. It is similar to FDM but specifically used for light waves in fiber-optic communications.

৮৪.
What is the bandwidth requirement for a Frequency Modulation (FM) signal?
  1. Same as the message signal
  2. Proportional to the square of the frequency deviation
  3. Equal to the carrier frequency
  4. Infinite
ব্যাখ্যা

Explanation:  FM signal bandwidth is determined by the frequency deviation and the message signal frequency, and it increases with larger frequency deviation.
Why the other options are incorrect:
ক) Same as the message signal: The bandwidth for FM is not the same as the message signal's bandwidth. FM typically requires a much wider bandwidth than the baseband message signal.
গ) Equal to the carrier frequency: This is not correct. The FM bandwidth depends on the frequency deviation and the message signal bandwidth, not just the carrier frequency.
ঘ) Infinite: Although FM does theoretically have an infinite number of sidebands (in a mathematical sense), the actual bandwidth is finite and depends on the modulation index and message bandwidth. Carson's Rule provides an estimate for practical FM bandwidth.

৮৫.
What is the principle behind Spread Spectrum techniques?
  1. Spreading the signal over a wider bandwidth
  2. Varying the amplitude of the carrier
  3. Increasing the transmission power
  4. Using a high frequency carrier
ব্যাখ্যা

Explanation:
Spread Spectrum techniques are a group of modulation methods that spread a signal over a much wider bandwidth than the minimum required. The idea is to make the transmitted signal less susceptible to interference, jamming, and eavesdropping by using a broad frequency spectrum. The signal is spread over a larger bandwidth, which also allows for multiple users to share the same frequency band in systems like CDMA (Code Division Multiple Access).

Two main types of Spread Spectrum techniques are:

Frequency Hopping: The carrier frequency hops between different channels over time.
Direct Sequence: The signal is multiplied by a "spreading code" that increases its bandwidth.
Why the other options are incorrect:
খ) Varying the amplitude of the carrier: This is related to Amplitude Modulation (AM) or Amplitude Shift Keying (ASK), but not Spread Spectrum techniques.
গ) Increasing the transmission power: Spread Spectrum does not inherently require increasing transmission power. It spreads the signal over a larger bandwidth but does not directly impact power levels.
ঘ) Using a high frequency carrier: While Spread Spectrum techniques can be used with high-frequency carriers, the primary principle is about spreading the signal over a wide bandwidth, not just using high frequency carriers.

৮৬.
What is the main advantage of Code Division Multiple Access (CDMA) in communication systems?
  1. High bandwidth utilization
  2. Increased signal strength
  3. Resistance to interference
  4. Lower energy consumption
ব্যাখ্যা

Explanation:
Code Division Multiple Access (CDMA) is a technique used in communication systems where multiple signals are transmitted over the same frequency band by assigning each signal a unique code. The main advantage of CDMA is its resistance to interference because each user's signal is spread over a wide bandwidth and distinguished by a unique code. This makes CDMA systems robust to noise and interference from other signals, as only the intended signal with the correct code can be correctly decoded.

Why the other options are incorrect:
ক) High bandwidth utilization: While CDMA can efficiently utilize bandwidth by allowing multiple users to share the same frequency spectrum, the primary advantage of CDMA is resistance to interference, not just bandwidth utilization.
খ) Increased signal strength: CDMA does not inherently increase the signal strength. It helps reduce interference and enables simultaneous communication from multiple users, but it doesn't directly impact the power level of the signal.
ঘ) Lower energy consumption: CDMA is not specifically designed to reduce energy consumption. While some forms of communication systems might optimize power usage, CDMA is mainly focused on improving interference resistance and capacity.

৮৭.
Which of the following is a characteristic of a microprocessor?
  1. It contains memory
  2. It only processes data
  3. It has integrated I/O ports
  4. It has no built-in peripherals
ব্যাখ্যা

Explanation:
Modern microprocessors are designed to be more integrated and versatile. As part of their integration, many microprocessors now include integrated I/O (Input/Output) ports, which allow them to directly communicate with external devices (like sensors, displays, or storage devices) without needing additional external chips.

Why the other options are incorrect:
ক) It contains memory: Microprocessors themselves do not typically contain memory; rather, they interface with external memory (such as RAM or ROM). While some microprocessors may have small amounts of internal cache memory, they are generally not designed to store large amounts of data.
খ) It only processes data: While processing data is the core function of a microprocessor, it also controls other components like memory and peripherals and often handles tasks like communication, timing, and power management. So, it doesn't only process data.
ঘ) It has no built-in peripherals: This is incorrect because modern microprocessors do have built-in peripherals like I/O ports, timers, serial communication interfaces, and more. These peripherals are integrated into the microprocessor to reduce the need for additional external components.

৮৮.
Which of the following is the clock speed of the 8086 microprocessor?
  1. 4 MHz
  2. 5 MHz
  3. 12 MHz
  4. 15 MHz
ব্যাখ্যা

Explanation:
The Intel 8086 microprocessor was initially released with a clock speed of 5 MHz. It was one of the first widely-used 16-bit microprocessors and came with clock speeds of 4 MHz, 5 MHz, and later higher speeds like 8 MHz.

Why the other options are incorrect:
ক) 4 MHz: The 8086 did have a version that operated at 4 MHz, but 5 MHz was more commonly used as the standard clock speed.
গ) 10 MHz: The 8086 did not initially operate at 10 MHz. It was available at lower speeds like 4 MHz and 5 MHz, with later models (like the 8086-2) operating at higher speeds, but 10 MHz was not a typical standard for the 8086.
ঘ) 15 MHz: While 15 MHz versions were available later (such as the 8086-2), the standard clock speed for the early 8086 microprocessor was 5 MHz.

৮৯.
What is the number of bits used for addressing memory in the 8086 microprocessor?
  1. 8 bits
  2. 16 bits
  3. 20 bits
  4. 32 bits
ব্যাখ্যা

Explanation:
The 8086 microprocessor uses 20 bits for addressing memory. This means it can address 2^20 memory locations, which equals 1 MB (megabyte) of addressable memory. The 8086 uses a segmented memory model with 16-bit registers, but the physical memory address is 20 bits wide.

Why the other options are incorrect:
ক) 8 bits: The 8086 microprocessor does not use 8 bits for addressing memory. It uses a 20-bit address bus.
খ) 16 bits: The 8086 uses 16-bit registers and operations, but it addresses memory with a 20-bit address bus, allowing it to access more than just 64 KB of memory.
ঘ) 32 bits: The 8086 is a 16-bit microprocessor, and it does not have a 32-bit address bus. The 20-bit address bus is used for memory addressing.

৯০.
Which of the following memory types is non-volatile?
  1. RAM
  2. ROM
  3. Cache
  4. Registers
ব্যাখ্যা

Explanation:
ROM (Read-Only Memory) is non-volatile memory, meaning that it retains its data even when the power is turned off. It is typically used to store firmware or system-level software that needs to remain intact across reboots and power cycles.

Why the other options are incorrect:
ক) RAM (Random Access Memory): RAM is volatile, meaning it loses all data when the power is turned off. It is used for temporary storage while the system is running.
খ) Cache: Cache memory is also a form of volatile memory, designed for fast access to frequently used data. It loses its data when the power is off.
ঘ) Registers: Registers are small, fast storage locations inside the processor that hold data temporarily during processing. They are volatile and lose their data when the system is powered down.

৯১.
Which of the following instructions is used for  unsigned  multiplication in the 8086?
  1. MUL
  2. IMUL
  3. DIV
  4. IDIV
ব্যাখ্যা

Explanation: The **MUL** instruction is used for unsigned multiplication in the 8086. It multiplies the contents of the accumulator (AX) by the operand and stores the result in the AX and DX registers.

  ক) MUL – Correct. This instruction is for unsigned multiplication.
  খ) IMUL – Incorrect.  IMUL is used for signed multiplication.
  গ) DIV – Incorrect. DIV is used for division.
  ঘ) IDIV – Incorrect. IDIV is used for signed division.

৯২.
What happens when the derivative term is added to a PID controller?
  1. The system response becomes slower
  2. The system can anticipate future error
  3. The steady-state error increases
  4. The system becomes less sensitive to high-frequency noise
ব্যাখ্যা

Explanation:
When the derivative term is added to a PID (Proportional-Integral-Derivative) controller, it provides anticipatory action. This means that the controller responds not only to the current error but also to the rate of change of the error, allowing the system to anticipate future changes in the error. By doing so, it helps improve the system's stability and transient response.

Let’s go through the other options:
ক) The system response becomes slower:
This is not correct. Adding the derivative term typically helps the system respond faster to changes in error, as it anticipates future errors. It improves the transient response of the system and reduces overshoot.
গ) The steady-state error increases:
This is incorrect. The derivative term doesn't directly affect the steady-state error. The steady-state error is primarily influenced by the integral term in a PID controller, which eliminates steady-state error over time. The derivative term helps with the transient response, not steady-state error.
ঘ) The system becomes less sensitive to high-frequency noise:
This is also incorrect. The derivative term can actually amplify high-frequency noise, because it responds to the rate of change of the error. High-frequency noise in the error signal can lead to unwanted oscillations in the system. To reduce sensitivity to high-frequency noise, a low-pass filter is typically added to the derivative term.

৯৩.
Which of the following is used to decode I/O addresses?
  1. Address decoder
  2. I/O port
  3. Memory controller
  4. I/O controller
ব্যাখ্যা

Explanation:
An address decoder is used to decode I/O (Input/Output) addresses. It translates the I/O address generated by the processor into a specific I/O device or port. This allows the processor to communicate with the correct peripheral device (like a printer, keyboard, or disk drive) based on the address.

Why the other options are incorrect:
খ) I/O port: An I/O port is an interface used for communication between the processor and peripheral devices but doesn't decode the I/O address. It simply serves as a channel for data exchange.
গ) Memory controller: A memory controller manages access to memory (RAM), not I/O addresses. It handles the read and write operations to memory but does not decode I/O addresses.
ঘ) I/O controller: An I/O controller manages communication with I/O devices but doesn't decode the I/O address. It works in conjunction with the decoded address provided by the address decoder to handle I/O operations.

৯৪.
Which of the following devices is commonly interfaced to the 8086 for generating precise time intervals?
  1. 8255A
  2. 8254
  3. 8259A
  4. 8284A
ব্যাখ্যা

Explanation: The 8254 is a programmable interval timer used to generate precise time intervals and manage delays for time-sensitive operations in systems like the 8086 microprocessor.

ক) 8255A – Incorrect. The 8255A is a programmable peripheral interface, not a timer.
খ) 8254 – Correct. The 8254 is a programmable interval timer that generates precise timing intervals.
গ) 8259A – Incorrect. The 8259A is an interrupt controller, not a timer.
ঘ) 8284A – Incorrect. The 8284A is a clock generator, but it does not generate specific timing intervals.

৯৫.
The 8086 microprocessor supports which of the following interrupt types?
  1. Hardware interrupts
  2. Software interrupts
  3. Both A and B
  4. None of the above
ব্যাখ্যা

Explanation:
The 8086 microprocessor supports both hardware interrupts and software interrupts.

Hardware Interrupts: These interrupts are generated by external devices (such as I/O devices or hardware peripherals) to request the attention of the processor. The 8086 has specific pins to handle hardware interrupts (e.g., INTR and NMI).
Software Interrupts: These interrupts are generated by the program itself, often through an instruction such as the INT instruction in the 8086 assembly language. Software interrupts are used to call system routines or handle specific software-defined tasks.
Why the other options are incorrect:
ক) Hardware interrupts: The 8086 does support hardware interrupts, but it also supports software interrupts, so this option is incomplete.
খ) Software interrupts: While the 8086 does support software interrupts, it also supports hardware interrupts, making this option incomplete as well.
ঘ) None of the above: This is incorrect because the 8086 indeed supports both hardware and software interrupts.

৯৬.
In 8086, how are the data registers categorized?
  1. General purpose registers
  2. Special purpose registers
  3. Both A and B
  4. None of the above
ব্যাখ্যা

Explanation: The 8086 microprocessor has both **general-purpose registers** (like AX, BX, CX) and **special-purpose registers** (like IP, SP) for specific tasks.
ক) General purpose registers – Incorrect. While the 8086 has general-purpose registers, it also has special-purpose registers.
খ) Special purpose registers – Incorrect. The 8086 uses both general-purpose and special-purpose registers.
গ) Both A and B – Correct. The 8086 has both general-purpose and special-purpose registers.
ঘ) None of the above – Incorrect. The 8086 contains both types of registers.

৯৭.
Which type of memory is used in the 8086 for storing instructions?
  1. Cache memory
  2. SSD
  3. ROM
  4. All of the above
ব্যাখ্যা

Explanation:
In the 8086 microprocessor, RAM (Random Access Memory) is typically used to store instructions. The 8086 fetches instructions from RAM during the execution of programs. RAM allows both read and write operations, making it suitable for storing instructions that change during program execution.

Why the other options are incorrect:
ক) Cache memory: Cache memory is used for storing frequently accessed data to speed up access times, but it is not primarily used for storing instructions in the 8086. Cache memory is an auxiliary component that speeds up data retrieval but is not directly where instructions are stored.
গ) ROM: ROM (Read-Only Memory) is typically used for storing firmware or boot-up code, such as the BIOS, and is not used to store regular instructions during the execution of a program in 8086.
ঘ) All of the above: While cache memory and ROM play important roles in computer systems, RAM is the primary type of memory used for storing instructions that are being executed.

৯৮.
The 8086 processor has how many segment registers?
  1. 2
  2. 4
  3. 6
  4. 8
ব্যাখ্যা

Explanation:
The 8086 microprocessor has 4 segment registers. These are used to manage memory segmentation in the system. The 4 segment registers are:

CS (Code Segment): Holds the segment address for the currently executing program code.
DS (Data Segment): Used for accessing data.
SS (Stack Segment): Used for stack operations.
ES (Extra Segment): Typically used for additional data storage, like for string operations.
These segment registers help the 8086 processor to address more memory than the size of the 16-bit registers would allow by using the segment:offset method for addressing.

৯৯.
What is the function of the 8086's instruction pointer (IP) register?
  1. Stores the address of the next instruction
  2. Stores the return address of a function
  3. Stores the data to be processed
  4. Stores the flags
ব্যাখ্যা

Explanation:
The Instruction Pointer (IP) register in the 8086 microprocessor holds the address of the next instruction to be fetched and executed. The IP is a 16-bit register that works in conjunction with the CS (Code Segment) register to form the 16-bit segment:offset address to access the next instruction in memory.

The IP register automatically increments after each instruction fetch, pointing to the next instruction in sequence unless modified by control flow instructions like jump or call.
Why the other options are incorrect:
খ) Stores the return address of a function: This is the function of the stack and the return address is typically stored on the stack. The IP stores the address of the next instruction to execute, not the return address.
গ) Stores the data to be processed: The IP does not store data; it stores the address of the instruction to be executed. Data is stored in registers or memory.
ঘ) Stores the flags: The flags are stored in the FLAGS register, not the IP. The FLAGS register holds the status of the processor, such as carry, zero, sign, etc.

১০০.
The 8086 microprocessor operates in which mode by default?
  1. Real mode
  2. Protected mode
  3. Virtual mode
  4. Hybrid mode
ব্যাখ্যা

Explanation: The 8086 microprocessor operates in **real mode** by default, meaning it can access only up to 1MB of memory and has no memory protection or multitasking capabilities. This mode was used in early PCs.

ক) Real mode – Correct. In real mode, the processor accesses memory directly and runs one program at a time.
খ) Protected mode – Incorrect. Protected mode, introduced with the 80386, allows for memory protection and larger memory addressing.
গ) Virtual mode – Incorrect. Virtual mode is not used by the 8086, and it was first introduced in later processors like the 80386.
ঘ) Hybrid mode – Incorrect. Hybrid mode combines real and protected modes, a feature of later processors, not the 8086.

১০১.
Which of the following is the simplest form of a control system?
  1. Open-loop control
  2. Closed-loop control
  3. Feedforward control
  4. Adaptive control
ব্যাখ্যা

Explanation:
Open-loop control systems operate without feedback, using a fixed input to produce the desired output. They are the simplest form of control systems, as they do not monitor the system's output.

ক) Open-loop control – Correct. This type of system lacks feedback and relies solely on the input to control the output.
খ) Closed-loop control – Incorrect. Closed-loop systems use feedback to adjust the system's output.
গ) Feedforward control – Incorrect. Feedforward control anticipates changes and adjusts inputs accordingly but still uses feedback.
ঘ) Adaptive control – Incorrect. Adaptive control systems adjust their parameters in real-time based on system behavior, which makes them more complex than open-loop systems.

১০২.
What does the 'D' in a PID controller stand for?
  1. Derivative
  2. Differential
  3. Delayed
  4. Displacement
ব্যাখ্যা

Explanation:
In a PID controller, the 'D' stands for **Derivative**. This term is used to calculate the rate of change of the error, helping to improve system stability and minimize oscillations.

ক) Derivative – Correct. The derivative term in PID control helps anticipate future errors based on the rate of change.
খ) Differential – Incorrect. While this might seem similar, 'Differential' is not the correct term used in PID controllers.
গ) Delayed – Incorrect. The 'D' does not represent 'Delayed'; it's used to refer to the rate of change of the error.
ঘ) Displacement – Incorrect. Displacement is not related to PID control.

১০৩.
In a Type 1 system, which error constant is used for a ramp input?
  1. Position error constant
  2. Velocity error constant
  3. Acceleration error constant
  4. Jerk error constant
ব্যাখ্যা

Explanation: In a Type 1 control system, the **velocity error constant (Kv)** is used to eliminate steady-state error for a ramp input. Type 1 systems can respond to ramp inputs without accumulating error in steady state.

ক) Position error constant – Incorrect. The position error constant (Kp) is used for step inputs.
খ) Velocity error constant – Correct. Kv is used for ramp inputs in Type 1 systems.
গ) Acceleration error constant – Incorrect. This constant is relevant for Type 2 systems, not Type 1.
ঘ) Jerk error constant – Incorrect. Jerk error constant is not typically associated with Type 1 or Type 2 systems.

১০৪.
Which of the following is NOT a standard control system input?
  1. Step input
  2. Ramp input
  3. Sinusoidal input
  4. Exponential input
ব্যাখ্যা

Explanation:
In control systems, the standard input types are typically those that are used to analyze system responses. The common standard inputs are:

ক) Step input: This represents a sudden change in input, such as switching a signal on or off, commonly used to study transient and steady-state behavior.
খ) Ramp input: This represents a continuously increasing (or decreasing) input over time, often used to study how a system responds to a linearly changing input (like velocity tracking).
গ) Sinusoidal input: A sinusoidal input (sine wave) is used to analyze the system's frequency response and behavior under periodic inputs.
However, an exponential input is not typically considered a standard input for control systems analysis, although it can be used in some specialized contexts. Exponential inputs are not as commonly used as step, ramp, or sinusoidal inputs in classical control systems.

১০৫.
What type of system is considered to be marginally stable?
  1. A system with complex conjugate poles on the right half-plane
  2. A system with complex conjugate poles on the imaginary axis
  3. A system with poles in the left half-plane
  4. A system with no poles
ব্যাখ্যা

Explanation:
A marginally stable system is one where the poles of the system lie on the imaginary axis of the s-plane (the complex plane). Specifically, these poles are usually in the form of complex conjugate poles with zero real parts, meaning they have an oscillatory behavior but don't grow or decay. This is often observed in systems that oscillate at a constant amplitude (e.g., a sinusoidal response) without diverging.

Why the other options are incorrect:
ক) A system with complex conjugate poles on the right half-plane: A system with poles on the right half-plane is considered unstable, not marginally stable. These poles correspond to exponential growth in the system's response.
গ) A system with poles in the left half-plane: A system with all poles in the left half-plane is considered stable, meaning the system's response decays over time.
ঘ) A system with no poles: A system with no poles would be highly unconventional and typically not a meaningful physical system in control theory.

১০৬.
Which of the following components is responsible for generating the clock signals in a microprocessor system?
  1. Clock generator IC
  2. CPU
  3. Timer
  4. Memory controller
ব্যাখ্যা

Explanation: The **Clock generator IC** is responsible for providing the clock signal that synchronizes the operations of the microprocessor and other components.

ক) Clock generator IC – Correct. The clock generator IC, such as the 8284A, generates the clock signals for the processor.
খ) CPU – Incorrect. The CPU performs computations but does not generate the clock signal.
গ) Timer – Incorrect. Timers are used for specific time-related operations but not for generating the clock signal.
ঘ) Memory controller – Incorrect. Memory controllers manage data access but are not responsible for clock generation.

১০৭.
Which of the following memory types is typically used for storing program instructions in embedded systems?
  1. Flash memory
  2. Cache memory
  3. Dynamic RAM
  4. Static RAM
ব্যাখ্যা

Explanation:
In embedded systems, Flash memory is commonly used for storing program instructions because it is non-volatile, meaning it retains data even when the power is turned off. Flash memory is often used to store the firmware or operating system code in embedded devices, as it can be easily rewritten or updated while maintaining the ability to persist the instructions across power cycles.

Why the other options are incorrect:
খ) Cache memory: Cache memory is a type of high-speed memory used to store frequently accessed data or instructions to speed up processor operations. It is volatile, meaning it loses its data when power is off, and is not typically used for long-term storage of program instructions.
গ) Dynamic RAM (DRAM): DRAM is used for general-purpose volatile storage in many systems, but it is not typically used for storing program instructions in embedded systems. DRAM needs to be refreshed regularly, which makes it less suitable for storing the program code that needs to persist between power cycles.
ঘ) Static RAM (SRAM): SRAM is faster than DRAM and used for temporary storage and cache memory, but it is also volatile and requires continuous power to maintain data. It is typically not used to store program instructions in embedded systems.

১০৮.
Which of the following is the primary function of the control unit in a microprocessor?
  1. Perform arithmetic operations
  2. Fetch and decode instructions
  3. Store data in registers
  4. Manage I/O operations
ব্যাখ্যা

Explanation: The **Control Unit (CU)** is responsible for fetching instructions from memory, decoding them to understand the required operation, and directing the CPU's actions accordingly.

- A) Perform arithmetic operations – Incorrect. The ALU (Arithmetic Logic Unit) performs arithmetic operations, not the control unit.
- B) Fetch and decode instructions – Correct. The control unit coordinates the execution of instructions by fetching and decoding them.
- C) Store data in registers – Incorrect. Registers store data during execution, but this is not the responsibility of the control unit.
- D) Manage I/O operations – Incorrect. I/O operations are handled by external I/O controllers, not the control unit.

১০৯.
The 8086 microprocessor has how many bits in its data bus?
  1. 8 bits
  2. 16 bits
  3. 32 bits
  4. 64 bits
ব্যাখ্যা

Explanation: The 8086 microprocessor has a **16-bit data bus**, meaning it can process 16 bits of data at a time. This was a significant advancement over earlier 8-bit processors.

ক) 8 bits – Incorrect. The 8086 has a 16-bit data bus, not 8 bits.
খ) 16 bits – Correct. The 8086 processor is a 16-bit processor, with a 16-bit data bus for handling data.
গ) 32 bits – Incorrect. The 8086 uses a 16-bit data bus, while 32-bit data buses were introduced with later processors.
ঘ) 64 bits – Incorrect. The 8086 does not use a 64-bit data bus.

১১০.
Which of the following is NOT a function of a microprocessor?
  1. Arithmetic operations
  2. Logical operations
  3. Data storage (like RAM/ROM)
  4. Control of input/output
ব্যাখ্যা

Explanation:
A microprocessor’s job is mainly:

Performing arithmetic operations (addition, subtraction, etc.)
Performing logical operations (AND, OR, NOT, comparisons)
Controlling input/output devices (through control signals and buses)
But it cannot store data permanently. For memory (RAM/ROM/Cache), the system needs external storage devices.