222 ±ÜÅÍæ° ±ÜâÔ¤pæ ÍæÅà~ ¯©ìÐÜr ±Ü£Åpæ *222/a* akpsc.kar.nic.in/222...
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222 (1 – A )
D ±ÜÅÍæ°±ÜâÔ¤Pæ¿á®Üá° ñæÃæ¿ááÊÜíñæ ¯ÊÜáWæ £ÚÓÜáÊÜÊÜÃæWÜã C¨Ü®Üá° ñæÃæ¿áPÜãvÜ Üá
±ÜÅÍæ° ±ÜâÔ¤Pæ ÍæÅà~
±ÜÅÍæ° ±ÜâÔ¤Pæ
¯©ìÐÜr ±Ü£ÅPæ (±Ü£ÅPæ II)
ÓÜÊÜá¿á : 2 WÜípæWÜÙÜá WÜÄÐÜu AíPÜWÜÙÜá : 200
ÓÜãaÜ®æWÜÙÜá 1. ±ÜÄàûæ ±ÝÅÃÜí»ÜWæãívÜ ñÜûÜ|Êæà J.Gí.BÃ…. EñܤÃÜÖÝÙæ¿áÈÉ ±ÜÅÍæ° ±ÜâÔ¤Pæ ÍæÅà~¿á®Üá° WÜáÃÜáñÜá ÊÜÞvÜáÊÜ Êæã¨ÜÆá, D ±ÜÅÍæ° ±ÜâÔ¤Pæ¿áÈÉ
ÊÜáá©ÅñÜÊÝWÜ Ü A¥ÜÊÝ ÖÜÄ©ÃÜáÊÜ A¥ÜÊÝ ¿ÞÊÜâ æà ±Üâo CÆÉ©ÃÜáÊÜ A¥ÜÊÝ ÊÜáá©ÅñÜÊÝWÜ Ü ±ÜÅÍæ°WÜÙÜá CñÝ© JÙÜWæãíwÆÉÊæíŸá¨Ü®Üá° ¯àÊÜâ ±ÜÄàüÓÜñÜPÜR Üáª. Êæáà騆 ¿ÞÊÜâ æà ¨æãàÐÜ PÜívÜáŸí ÜÈÉ A¨Ü®Üá° ×í£ÃÜáXÔ Æ»ÜÂËÃÜáÊÜ ÍæÅà~¿á ±ÜıÜä|ìÊÝ Ü ¸æàÃæ ±ÜÅÍæ° ±ÜâÔ¤Pæ¿á®Üá° ±Üvæ¿áñÜPÜR¨Üáª.
2. A»Ü¦ì¿áá ±ÜÅÍæ° ±ÜâÔ¤Pæ¿á ÍæÅà~ A, B, C A¥ÜÊÝ D A®Üá° ËÐÜ¿á ÓÜíPæàñÜ ÊÜáñÜᤠ®æãàí Ü~ ÓÜíTæ¿á®Üá° OMR EñܤÃÜ ±Ü£ÅPæ¿áÈÉ A¨ÜPÝRX J¨ÜXÓÜÇÝXÃÜáÊÜ ÓܧÙܨÜÈÉ ŸÃæ¨Üá ÓÜíPæàñÜ (G®… Pæãàv…) WæãÚÓܸæàPÜá. ÖÝWÜã ¯WÜ©ñÜ ÓܧÙÜ ÜÈÉ ñÝÊÜâ ÊÜáñÜᤠÓÜíËàûÜPÜÃÜá ÓÜ× ÊÜÞwÃÜáÊÜâ¨Ü®Üá° SbñÜ ±ÜwÔPæãÙÜÛ æàPÜá. J.Gí.BÃ…. ÖÝÙæ¿áÈÉ £ÚÔÃÜáÊÜ ¿ÞÊÜâ¨æà ÊÜÞ×£¿á®Üá° »Ü£ì ÊÜÞvÜáÊÜâ Üá/G®… Pæãàv… ÊÜÞvÜáÊÜâ¨Üá A»Ü¦ìWÜÙÜ gÊݸݪĿÞXÃÜáñܤ¨æ. Jí¨Üá ÊæàÙæ »Ü£ì ÊÜÞvÜ©¨ÜªÈÉ/ñܲ³¨ÜÈÉ AíñÜÖÜ J.Gí.BÃ…. EñܤÃÜ ÖÝÙæ¿á®Üá° £ÃÜÓÜRÄÓÜÇÝWÜáÊÜâ Üá.
3. ±ÜPÜR ÜÈÉ J ÜXÔÃÜáÊÜ aèPÜ ÜÇæÉà ¯ÊÜá¾ ®æãàí Ü~ ÓÜíTæ¿á®Üá°
®ÜÊÜáã©ÓÜ æàPÜá. ±ÜÅÍæ° ±ÜâÔ¤Pæ¿áÈÉ ¸æàÃæ H®Ü®Üã° ŸÃæ¿á¸ÝÃܨÜá.
4. D ±ÜÅÍæ° ±ÜâÔ¤Pæ 100 ±ÜÅÍæ°WÜÙÜ®Üá° JÙÜWæãíwÃÜáñܤ æ. ±ÜÅ£Áãí¨Üá ±ÜÅÍæ°¿áá 4 ±ÜÅ£QÅÁáWÜÙÜ®Üá° (EñܤÃÜWÜÙÜ®Üá°) JÙÜWæãíwÃÜáñܤ æ. ¯àÊÜâ EñܤÃÜ ÖÝÙæ¿áÈÉ WÜáÃÜáñÜá ÊÜÞvܸæàPæ¯ÓÜáÊÜ EñܤÃÜÊÜ®Üá° BÁáR ÊÜÞwPæãÚÛ. Jí Üá ÊæàÙæ AÈÉ Jí¨ÜQRíñÜ ÖæaÜác ÓÜÄ¿Þ Ü EñܤÃÜWÜÚÊæÁáí¨Üá ¯àÊÜâ »ÝËÔ¨ÜÃæ ¯ÊÜáWæ AñÜáÂñܤÊÜáÊæ ÓÜáÊÜ EñܤÃÜPæR WÜáÃÜáñÜá ÊÜÞw. H®æà A¨ÜÃÜã ±ÜÅ£ ±ÜÅÍæ°Wæ ¯àÊÜâ PæàÊÜÆ Jí Üá EñܤÃÜÊÜ®Üá° ÊÜÞñÜÅ BÁáR ÊÜÞvÜ æàPÜá.
5. GÇÝÉ EñܤÃÜWÜÙÜ®Üá° ¯ÊÜáWæ J ÜXÓÜÇÝXÃÜáÊÜ ±ÜÅñæÂàPÜ EñܤÃÜ ÖÝÙæ¿á ÊæáàÇæ PæàÊÜÆ PܱÜâ³ A¥ÜÊÝ ¯àÈ ÍÝÀá¿á ¸ÝÇ…±ÝÀáíp… ±æ °®ÜÈÉ ÊÜÞñÜÅ WÜáÃÜáñÜá ÊÜÞvÜ æàPÜá. J.Gí.BÃ…. EñܤÃÜ ±Ü£ÅPæ ÖÝÙæ¿áÈÉ®Ü ËÊÜÃÜÊÝ¨Ü ÓÜãaÜ®æWÜÙÜ®Üá° WÜÊÜá¯ÓÜáÊÜâ¨Üá.
6. GÇÝÉ ±ÜÅÍæ°WÜÚWæ ÓÜÊÜÞ®Ü AíPÜWÜÙÜá. GÇÝÉ ±ÜÅÍæ°WÜÚWæ EñܤÄÔÄ. ±ÜÅ£ ñܱÜâ³ EñܤÃÜPæR ±ÜÅÍæ°Wæ ¯WÜ©±ÜwÔ Ü AíPÜWÜÙÜ ¼ (0.25) ÃÜÐÜár AíPÜWÜÙÜ®Üá° PÜÙæ¿áÇÝWÜáÊÜâ Üá.
7. bñÜᤠPæÆÓÜPÝRX ÖÝÙæWÜÙÜ®Üá° ±ÜÅÍæ° ±ÜâÔ¤Pæ¿á Pæã®æ¿áÈÉ ÓæàÄÓÜÇÝX¨æ. ±ÜÅÍæ° ±ÜâÔ¤Pæ¿á C®Üá°Ú Ü ¿ÞÊÜ »ÝWܨÜÈÉ¿áã ¯àÊÜâ ¿ÞÊÜ Äࣿá WÜáÃÜáñÜ®Üá° ÊÜÞvÜñÜPÜR Ü ªÆÉ.
8. ±ÜÄàûæ¿á ÊÜááPݤ¿áÊÜ®Üá° ÓÜãbÓÜáÊÜ Aí£ÊÜá WÜípæ ¸ÝÄÔ Ü ñÜûÜ|Êæà EñܤÃÜ ±Ü£ÅPæ ÖÝÙæ¿áÈÉ C®Ý°ÊÜâ¨æà WÜáÃÜáñÜá ÊÜÞvÜáÊÜâ Ü®Üá° ¯ÈÉÓܸæàPÜá. ÓÜíËàûÜPÜÃÜá Ÿí¨Üá ¯ÊÜá¾ÈÉÃÜáÊÜ EñܤÃÜ ÖÝÙæ¿á®Üá° ñÜÊÜá¾ ÊÜÍÜPæR ±Üvæ ÜáPæãívÜá ÇæPÜRPæR ñæWæ¨ÜáPæãÙÜáÛÊÜÊÜÃæWÜã ¯ÊÜá¾ ¯ÊÜá¾ BÓÜ®Ü ÜÈÉÁáà PÜáÚ£ÃÜñÜPÜR Üáª.
9. ±ÜÅÍæ°WÜÙÜá PܮܰvÜ ÊÜáñÜᤠBíWÜÉ »ÝÐæ¿áÈÉÃÜáñܤÊæ. PܮܰvÜ ±ÜÅÍæ°WÜÙÜÈÉ ÓÜí¨æàÖÜ EípÝ ÜÃæ, Ü¿áËoár BíWÜÉ »ÝÐæ¿á ±ÜÅÍæ°WÜÙÜ® Üá° WÜÊÜá¯ÓÜáÊÜâ¨Üá. ±ÜÅÍæ° ±Ü£ÅPæ¿á ±ÜÅÍæ°WÜÙÜÈÉ ¿ÞÊÜâ¨æà Wæãí¨ÜÆWÜڨܪÃÜã BíWÜÉ»ÝÐæ¿á ±ÜÅÍæ°WÜÙæà Aí£ÊÜáÊÝXÃÜáñܤ¨æ.
Note : English version of the instructions is printed on the back cover of this booklet.
A ËÐÜ¿á ÓÜíPæàñÜ : 222
*222/A*
®æãàí¨Ü~ ÓÜíTæÂ
¿ÞÊÜâ æà Äࣿá Êæã æçÇ… ¶æäà®…, PÝÂÇ…PÜáÂÇæàoÃ… ÊÜáñÜᤠCñÜÃæ Äࣿá GÇæPÝó¯P…/PÜÊÜáã¯PæàÐÜ®… ÓÝ«Ü®ÜWÜÙÜá CñÝ©WÜÙÜ®Üá° ±ÜÄàûÝ Pæàí¨ÜÅ Ü BÊÜÃÜ|¨æãÙÜWæ ñÜÃÜáÊÜâ Ü®Üá° ¯Ðæà˜Ô¨æ.
222 (2 – A )
1. l GzÀÝ ªÀÄvÀÄÛ ªÀÈwÛÃAiÀÄ CqÀØ ¹Ã½PÉ wædå r EgÀĪÀ
vÀAwAiÀÄ «zÀÄå¤ßgÉÆÃzsÀ R NªÀiïUÀ¼ÀÄ CzÉÃ
ªÀ¸ÀÄÛ«¤AzÀ ªÀiÁrzÀ E£ÉÆßAzÀÄ vÀAwAiÀÄ CqÀØ
¹Ã½PÉ wædå 2r EgÀĪÀ vÀAwAiÀÄ «zÀÄå¤ßgÉÆÃzsÀªÀÇ
¸ÀºÀ R EgÀĪÀÅzÀÄ, GzÀݪÀÅ E¶ÖzÁÝUÀ
(1) 2𝑙
(2) 𝑙
2
(3) 4𝑙
(4) 𝑙2
2. 100 ªÁåmï «zÀÄåvï §¯ïâ ¸ÀgÁ¸Àj ¢£ÀPÉÌ 10 UÀAmÉAiÀÄAvÉ MAzÀÄ ªÁgÀ PÁ® GjAiÀÄĪÀÅzÀÄ. 1 ªÁgÀzÀ ±ÀQÛAiÀÄ §¼ÀPÉ _________ AiÀÄƤmïUÀ¼ÀÄ.
(1) 7
(2) 70
(3) 0.7
(4) 0.07
3. ¸ÀgÁ¸Àj ªÁå¸À 30 ¸É.«ÄÃ. EgÀĪÀ GAUÀÄgÀzÀ ¸ÀÄvÀÛ 200 ¸ÀÄvÀÄÛ vÁªÀÄæzÀ vÀAw ¸ÀÄvÀÛ¯ÁVzÀÄÝ CzÀgÀ°è 2A «zÀÄåvÀàçªÁºÀ ºÀjAiÀÄÄwÛzÉ. CzÀgÀ GAUÀÄgÀzÀ PÁAwÃAiÀÄ ªÀ¸ÀÄÛ«£À CqÀØ ¹Ã½PÉ 12 ¸É.«ÄÃ2 EzÀÄÝ CzÀgÀ ¸Á¥ÉÃPÀë ªÁå¥ÀåvÉ 1000. CzÀgÀ ªÀÄÆ®PÀ ¸ÁUÀĪÀ ¥sÀèPïì
(1) 0.064 mwb
(2) 0.64 mwb
(3) 0.5 mwb
(4) 0.05 mwb
4. ¸ÁÜ¬Ä «zÀÄåvï ªÉÇïïÖ «ÄÃlgï£À ªÁå¦ÛAiÀÄ£ÀÄß
«¸ÀÛj¸À¨ÉÃPÁzÀgÉ »ÃUÉ ªÀiÁqÀ¨ÉÃPÀÄ
(1) ¸ÀgÀtÂAiÀÄ°è ¥ÉæÃgÀPÀ ¸ÉÃj¸À¨ÉÃPÀÄ
(2) ¸ÀgÀtÂAiÀÄ°è «zÀÄå¤ßgÉÆÃzsÀ ¸ÉÃj¸À¨ÉÃPÀÄ
(3) ªÉÇïïÖ «ÄÃlj£À ¸ÀgÀtÂAiÀÄ°ègÀĪÀ
zsÁgÀPÀQÌAvÀ PÀrªÉÄ zsÁgÀPÀvÉAiÀÄ zsÁgÀPÀ
(4) ªÉÇïïÖ «ÄÃlj£À ¸ÀgÀtÂAiÀÄ°ègÀĪÀ
zsÁgÀPÀQÌAvÀ C¢üPÀ zsÁgÀPÀvÉAiÀÄ zsÁgÀPÀ
5. ªÀÄÆgÀÄ ¸ÀªÀiÁ£À EA¦ÃqÉ£ïìUÀ¼À£ÀÄß ªÉÆzÀ®Ä
qɯÁÖzÀ°è 3- ¸ÀAvÀÄ°vÀ «zÀÄåvï ¥ÀÆgÉÊPÉUÉ
C¼ÀªÀr¹zÉ. CzÉà EA¦ÃqÉ£ïìUÀ¼À£ÀÄß CzÉÃ
¥ÀÆgÉÊPÉAiÀÄ°è ¸ÁÖlgïUÉ C¼ÀªÀr¹zÀgÉ
(1) ¥ÁæªÀ¸ÁÜ «zÀÄåvï ¥ÀæªÁºÀ ªÀÄÆgÀ£ÉÃ
MAzÀgÀµÀÄÖ
(2) vÀAw «zÀÄåvï ¥ÀæªÁºÀ ªÀÄÆgÀ£Éà MAzÀgÀµÀÄÖ
(3) §¼ÀPÉ DzÀ «zÀÄåvï ¸ÁªÀÄxÀåð ªÀÄÆgÀ£ÉÃ
MAzÀgÀµÀÄÖ
(4) F AiÀiÁªÀŪÀÇ C®è
222 (3 – A )
1) A wire of length l and of circular cross
section of radius r has a resistance of R
Ohms. Another wire of same material and
of cross sectional radius 2r will have the
same Resistance R if the length is
(1) 2𝑙
(2) 𝑙
2
(3) 4𝑙
(4) 𝑙2
2) A 100 watt light bulb burns on an average
of 10 hrs a day for one week. The weekly
consumption of energy will be ____ units.
(1) 7
(2) 70
(3) 0.7
(4) 0.07
3) A ring of mean diameter 30 cm is wound
with 200 turns of copper wire carrying a
current of 2 A. The cross sectional area of
the magnetic material of the ring is
12 cm2 and its relative permeability is
1000, the flux through it is
(1) 0.064 mwb
(2) 0.64 mwb
(3) 0.5 mwb
(4) 0.05 mwb
4) The range of an electrostatic voltmeter
can be extended by using
(1) An inductor in series
(2) A resistor in series
(3) A capacitor, of capacitance smaller
than that of voltmeter is series
(4) A capacitor of capacitance larger
than that of voltmeter in series
5) Three equal impedances are first
connected in delta across a 3- balanced
supply. If the same impedances are
connected in star across the same supply,
then
(1) Phase currents will be one third
(2) Line currents will be one third
(3) Power consumed will be one third
(4) None of the above
222 (4 – A )
6. F ¥ÉÊQ AiÀiÁªÀÅzÀÄ l«Äð£À¯ï ªÉÇïÉÖÃeï (V)
¯ÉÆÃqï PÀgÉAlÄ (IL) ®PÀëtUÀ¼À£ÀÄß r.¹. µÀAmï
GvÁàzÀPÀPÉÌ ¸ÀA§A¢ü¹zÀAvÉ ¥Àæw¤¢ü ÀÄvÀÛzÉ.
7. ¯ÉÆÃqï£À ªÉÄÃ¯É ¥ÀjÃQë¹zÁUÀ MAzÀÄ ¥ÀjªÀvÀðPÀ
(mÁæ£ïì¥sÁªÀÄðgï) ªÀÅ ±ÉÃ. 1.5% vÁªÀÄæ £ÀµÀÖªÀ£ÀÄß
ªÀÄvÀÄÛ 3.5% jAiÀiÁPÉÖ£ïì®Üá° ºÉÆA¢zÉ. EzÀÄ
GvÀÛªÀÄ ¤AiÀÄAvÀæt ºÉÆA¢gÀĪÀÅzÀÄ EzÀgÀ°è
(1) KPÀvÁ «zÀÄåvï CA±À
(2) 0.8 »AzÀĽPÉ «zÀÄåzÀA±À
(3) 0.8 ¯ÉÆÃrAUï «zÀÄåzÀA±À
(4) F ªÉÄð£À AiÀiÁªÀÅzÀÆ C®è
8. DªÉÄðZÀgïUÁV ¯ÉÆÃqï£À «zÀÄåvï CA±ÀªÀÅ
KPÀvɬÄzÁÝUÀ
(1) DªÉÄðZÀgï ¥sÀèPïè ZËPÀ vÀgÀAUÀ gÀÆ¥ÀzÀÄÝ
(2) DªÉÄðZÀgï ¥sÀèPïì ZËPÀ «PÁAwÃPÁgÀPÀ
(3) DªÉÄðZÀgï ¥sÀèPïè ZËPÀ CqÀØ PÁAwÃPÁgÀPÀ
(4) DªÉÄðZÀgï ¥sÀèPïè ZËPÀ ±ÀÆ£ÀåvÉUÉ PÀÄUÀÄΪÀÅzÀÄ
9. 3-¥ÁæªÀ¸ÉÜ, 6-¥ÉÆïï, 50 Hz ¥ÉæÃgÀPÀ ªÉÆÃlgÀÄ
5 ªÉÄnæPï JZï.¦. ¸ÁªÀÄxÀåðzÀ°è 950 rpm £À°è
wgÀÄUÀÄvÀÛzÉ. ¸ÉÊlgï £ÀµÀÖ 300 W DzÀgÉ ¸ÉÖÃlgï
DUÀvÀªÀÅ
(1) 5000 W
(2) 4755 W
(3) 4165 W
(4) 4015 W
222 (5 – A )
6) Which of the following curves represents
the terminal voltage (V), load current (IL)
characteristics of a DC shunt generator?
7) A transformer has copper loss of 1.5% and
reactance 3.5% when tested on load. It
will have better regulation at
(1) Unity power factor
(2) 0.8 lagging power factor
(3) 0.8 loading power factor
(4) None of the above
8) For an alternator when the power factor
of the load is unity
(1) The armature flux will have square
waveform
(2) The armature flux will be
demagnetizing
(3) The armature flux will be cross
magnetizing
(4) The armature flux will reduce to
zero
9) A 3-phase, 6-pole, 50 Hz induction motor
develops 5 metric H.P at 950 rpm. If the
stator loss is 300 W, the stator input must
be
(1) 5000 W
(2) 4755 W
(3) 4165 W
(4) 4015 W
222 (6 – A )
10. 3 ¥ÉæÃgÀPÀ ªÉÆÃlj£À EA¦ÃqÉ£ïì £ÀUÀtåªÁzÁUÀ
UÀjµÀ× sÁæªÀÄPÀzÀ°è£À ¹è¥ï (eÁjPÉ)
(1) √𝑟2
𝑥2
(2) √𝑥2
𝑟2
(3) 𝑟2
𝑥2
(4) 𝑥2
𝑟2
11. »£ÀÄßt¸ÀÄ EgÀzÀ ªÀzsÀðPÀzÀ°è UÀ½PÉ ¨ÁåAqï
ªÁå¦ÛAiÀÄ GvÀà£Àß 4 MHz. CzÀgÀ DªÀÈvÀ PÀÄtÂPÉ
UÀ½PÉ 40. ºÉƸÀ ¨ÁåAqï ªÁå¦ÛAiÀÄÄ
(1) 20 kHz
(2) 160 MHz
(3) 10 MHz
(4) 100 kHz
12. KPÀ ¥ÁæªÀ¸ÉÜ JgÀqÀÄ ¥À¯ïì ©æeï ¥ÀjªÀvÀðPÀªÀÅ
¸ÀgÁ¸Àj ¤UÀðvÀ ªÉÇïÉÖÃeï 400 V ¤ÃqÀÄvÀÛzÉ;
«zÀÄåvï ¸ÁªÀÄxÀåð 10 kW J¸ï¹DgïUÀ¼À£ÀÄß
¸ÀA¥ÀQð¹ KPÀ¥ÁæªÀ¸ÉÜ JgÀqÀÄ ¥À¯ïì ªÀÄzsÀå©AzÀÄ
¥ÀjªÀvÀðPÀ ªÀiÁqÀ¯ÁVzÉ. ºÉƸÀ ¤UÀðvÀ zÀgÀªÀÅ
(1) 400 V, 10 kW
(2) 400 V, 5 kW
(3) 200 V, 5 kW
(4) 200 V, 10 kW
13. LC ¸ÀgÀtÂAiÀÄ «zÀÄå£ÀäAqÀ®ªÀ£ÀÄß r¹
¥ÀÆgÉÊPɬÄAzÀ 100 V xÉÊj¸ÀÖgï ªÀÄÆ®PÀ
¥ÀÆgÉʹzÀÄÝ, xÉÊj¸ÀÖgï ªÀÄÆ®PÀ ºÀjAiÀÄĪÀ Cw
ºÉaÑ£À «zÀÄåvï ¥ÀæªÁºÀ
(1) 100√𝐿𝐶
(2) 100
√𝐿𝐶
(3) 100 (√𝐿
𝐶)
(4) 100 (√𝐶
𝐿)
222 (7 – A )
10) For a 3 induction motor when impedance
is neglected, the slip at the maximum
torque will be
(1) √𝑟2
𝑥2
(2) √𝑥2
𝑟2
(3) 𝑟2
𝑥2
(4) 𝑥2
𝑟2
11) An amplifier with no feedback has a gain
bandwidth product of 4 MHz. its DC
closed loop gain is 40. The new bandwidth
is
(1) 20 kHz
(2) 160 MHz
(3) 10 MHz
(4) 100 kHz
12) A single phase two pulse bridge convertor
gives an average output voltage of 400 V
and power of 10 kW. The SCRs are
connected to form a single phase two
pulse mid point convertor. The new
output rating will be
(1) 400 V, 10 kW
(2) 400 V, 5 kW
(3) 200 V, 5 kW
(4) 200 V, 10 kW
13) A LC series circuit is connected to a DC
supply of 100 V through a thyristor. The
peak current through the thyristor will be
(1) 100√𝐿𝐶
(2) 100
√𝐿𝐶
(3) 100(√𝐿
𝐶)
(4) 100(√𝐶
𝐿)
222 (8 – A )
14. ©.eÉ.n. AiÀÄ£ÀÄß ªÀzsÀðPÀªÁV §¼ÀPÉ ªÀiÁrzÁUÀ
CzÀÄ PÁAiÀÄð¤ªÀð»¸ÀĪÀÅzÀÄ
(1) ¥ÀAiÀiÁð¥ÀÛvÉAiÀÄ°è
(2) PÀmï D¥sï£À°è
(3) ¥ÀAiÀiÁð¥ÀÛvÉAiÉƼÀUÉ
(4) ¸ÀQæAiÀÄ ¥ÀæzÉñÀzÀ ªÉÄïÉ
15. C£ÀÄPÀæªÀÄ ¸Àj ¸ÀĪÀiÁjPÉ A/D ¥ÀjªÀvÀðPÀzÀ
¥ÀÈxÀPÀgÀt 20 mV ºÉÆA¢zÀÝgÉ rfl¯ï ¤UÀðvÀªÀÅ
C£ï¯ÁUï DUÀvÀ 2.17 V UÉ JµÀÄÖ ?
(1) 001101100
(2) 01101101
(3) 01101011
(4) ªÉÄð£À AiÀiÁªÀÅzÀÆ C®è
16. ¨sÁgÀvÀzÀAvÀºÀ zÉñÀzÀÈÉ UÁæ«ÄÃt
«zÀÄå¢ÃPÀgÀtzÉÆA¢UÉ ¸ÀAQÃtð eÁ®PÁÌV EzÀgÀ
§¼ÀPÉ C¥ÉÃPÀëtÂÃAiÀÄ
(1) UÁ½ vÀqÉ ¹.©.
(2) vÉÊ® ¹.©.
(3) ¤ªÁðvÀ ¹.©.
(4) JA.M.¹.©.
17. ªÀåªÀ¸ÉÜAiÀÄ°è UËæArAUï ¸ÀªÀÄ¥ÀðPÀªÁVzÉ JAzÀÄ
ºÉüÀ¨ÉÃPÁzÀgÉ DUÀ
(1) £ÀÆålæ¯ï C£ÀÄß £ÉÃgÀªÁV UËæArAUï ªÀiÁrgÀ¨ÉÃPÀÄ
(2) 𝑥0
𝑥1> 3.0 zÀ C£ÀÄ¥ÁvÀ
(3) 𝑅0
𝑥1> 2.0 zÀ C£ÀÄ¥ÁvÀ
(4) 𝑥0
𝑥1< 3.0 zÀ C£ÀÄ¥ÁvÀ
18. ºÉÊqÉ¯ï «zÀÄåvï ¸ÁܪÀgÀzÀ°è ºÀjªÀ £À¢AiÀÄ ¤ÃjUÉ
MqÀÄØ PÀlÄÖªÀÅzÀUÀvÀå CzÀjAzÁV
(1) ¸ÁܪÀgÀzÀ ¹ÜgÀ ¸ÁªÀÄxÀåð C¢üPÀªÁUÀĪÀÅzÀÄ
(2) PÁAiÀiÁZÀgÀuÉAiÀÄ ²gÀªÀÅ
¤AiÀÄAwævÀªÁUÀĪÀÅzÀÄ
(3) l¨ÉÊð£ï PÉùAUï(ªÀÄÄZÀѼÀ ºÉÆ¢PÉAiÀÄ°è£À)
£ÉƼÀV£À MvÀÛqÀ ¹ÜgÀªÁVgÀĪÀÅzÀÄ
(4) ºÀjªÀ ¤Ãj£À ZÀ®£À±ÀQÛAiÀÄ ¥ÀÆt𠧼ÀPÉ
DUÀĪÀÅzÀÄ
222 (9 – A )
14) When a BJT is employed as an amplifier,
it operates
(1) In saturation
(2) In cut off
(3) Well into saturation
(4) Over the active region
15) A successive approximation A/D converter
has a resolution of 20 mV. What will be
its digital output for an analog input of
2.17 V ?
(1) 001101100
(2) 01101101
(3) 01101011
(4) None of the above
16) For rural electrification in a country like
India with complex network it is
preferable to use
(1) Air break C.B.
(2) Oil C.B.
(3) Vacuum C.B.
(4) M.O.C.B.
17) A system is said to be effectively
grounded if its
(1) Neutral is grounded directly
(2) Ratio of 𝑥0
𝑥1> 3.0
(3) Ratio of 𝑅0
𝑥1> 2.0
(4) Ratio of 𝑥0
𝑥1< 3.0
18) A hydel power plant of run off river type
should be provided with a pondage so that
the
(1) Firm-Capacity of the plant is
increased
(2) Operating head is controlled
(3) Pressure inside the turbine spelling
remains constant
(4) Kinetic energy of the running water
is fully utilised.
222 (10 – A )
19. HVDC ¥Àæ¸ÀgÀtPÉÌ ¸ÀA§A¢ü¹zÀAvÉ F ¥ÉÊQ AiÀiÁªÀ ºÉýPÉ ¸ÀjAiÀÄ®è
(1) PÀgÉÆãÁ £ÀµÀÖªÀÅ HVDC ¥Àæ¸ÀgÀtzÀ°è E£ÀÆß C¢üPÀ
(2) ¢ézsÀÄæ«ÃAiÀÄ vÀAwAiÀÄ°è «zÀÄåvï ¥Àæ¸ÀgÀt ¸ÁªÀÄxÀåðªÀÅ ¸Àj¸ÀĪÀiÁgÀÄ KPÀ «zÀÄå£ÀäAqÀ® J.¹. vÀAwAiÀĵÉÖà EgÀĪÀÅzÀÄ
(3) HVDC ¸ÀA¥ÀPÀðªÀÅ JgÀqÀÄ AC ªÀåªÀ¸ÉÜUÀ¼À £ÀqÀÄªÉ ZÁ°ÛAiÀÄ°èzÀÄÝ EªÀÅUÀ¼À DªÀvÁðAPÀ MAzÉà DVgÀ¨ÉÃQ®è
(4) CAvÀUÀðvÀ PÉç¯ï¤AzÀ HVDC ¥Àæ¸ÀgÀtPÉÌ zÀÆgÀzÀ «Äw E®è
20. ±ÀÆ£Àå C£ÀÄPÀæªÀÄ «zÀÄåvï ¥ÀæªÁºÀªÀÅ vÀAw¬ÄAzÀ ¥ÀjªÀvÀðPÀ ¨ÁåAQUÉ ºÉÆÃUÀ¨ÉÃPÁzÀgÉ ¸ÀÄvÀÄÛUÀ¼ÀÄ »ÃVgÀ¨ÉÃPÀÄ
(1) UËæAqÉqï ¸ÁÖgï/qɯÁÖ
(2) qɯÁÖ/¸Ágï
(3) ¸ÁÖgï/UËæAqÉqï ¸ÁÖgï
(4) ¸ÁÖgï/qɯÁÖ
21. ¹APÀæ£À¸ï ªÉĶ£ï E = 1.1 pu £ÀÄß ºÉÆA¢zÀÄÝ, C£ÀAvÀgÀ §¸ï C£ÀÄß 1 pu ªÉÇïÉÖÃf£À°è ¥ÀÆgÉʸÀÄwÛzÉ. ªÀUÁðªÀuÉ jAiÀiÁPÉÖ£ïì 0.5 pu EzÀÝ°è ¸ÁܬĹÜw «zÀÄåvï ¸ÁªÀÄxÀåð «ÄwAiÀÄÄ
(1) 1.1 pu
(2) 0.55 pu
(3) 2.2 pu
(4) 2.6 pu
22. ¸ÀjAiÀiÁzÀ ºÉýPÉAiÀÄ£ÀÄß DAiÉÄÌ ªÀiÁr
(1) ¥ÁægÀA©üPÀ ¯ÉÆÃqï C¢üPÀªÁzÀµÀÆÖ ¸ÀA¢üUÀÞ
QèAiÀÄjAUï PÉÆãÀ C¢üPÀ
(2) ¥ÁægÀA©üPÀ ¯ÉÆÃqï C¢üPÀªÁzÀµÀÆÖ ¸ÀA¢üUÀÞ
QèAiÀÄjAUï PÉÆãÀ PÀrªÉÄ
(3) ¥ÁægÀA©üPÀ ¯ÉÆÃrUÀÆ ¸ÀA¢üUÀÞ QèAiÀÄjAUï
PÉÆãÀPÀÆÌ ¸ÀA§AzsÀ«®è
(4) PÁAiÀiÁðZÀgÀuÉ ªÀiÁqÀĪÀ CªÀ¢ü
«zÀÄå£ÀäAqÀ®zÀ bÉÃzÀPÀPÉÌ C¢üPÀªÁVzÀݵÀÆÖ
¸ÀA¢üUÀÞ QèAiÀÄjAUï PÉÆãÀªÀÇ C¢üPÀ
23. ºÉZÀÄѪÀjAiÀiÁUÀĪÀ EAzsÀ£À ªÉZÀѪÀÅ JgÀqÀÄ GvÁàzÀPÀ
PÉÃAzÀæUÀ½UÉ PÉÆnÖgÀĪÀÅzÀÄ IC1 = 25 + 0.2Pg1,
IC2 = 32 + 0.2Pg2, Pg1 ªÀÄvÀÄÛ Pg2 UÀ¼ÀÄ
¸ÁܪÀgÀUÀ½AzÀ GvÁà¢vÀªÁUÀĪÀ ¤d «zÀÄåvï
¸ÁªÀÄxÀåð MW AiÀÄƤmïUÀ¼À°è 250 MW MlÄÖ
¸ÁªÀÄxÀåð ¥ÀqÉAiÀÄ®Ä DyðPÀ «¤AiÉÆÃUÀ
_____________ (¥Àæ¸ÀgÀt £ÀµÀÖ £ÀUÀtå JAzÀÄ ¨sÁ«¹)
(1) Pg1 = 140.25 MW,
Pg2 = 109.75 MW
(2) Pg1 = 109.75 MW,
Pg2 = 140.25 MW
(3) Pg1 = Pg2 = 125 MW
(4) Pg1 = 100 MW, Pg2 = 150 MW
222 (11 – A )
19) Which of the following is not true
regarding HVDC transmission ?
(1) Corona loss is much more in HVDC
transmission
(2) The power transmission capability
of bipolar line is almost the same as
that of single circuit AC line
(3) HVDC link can operate between two
AC system whose frequencies need
not be equal
(4) There is no distance limitation for
HVDC transmission by underground
cable
20) Zero sequence currents can flow from a
line into a transformer bank if the
windings are in
(1) Grounded star/delta
(2) Delta/star
(3) Star/grounded star
(4) Star/Delta
21) A synchronous machine having
E = 1.1 pu is feeding an infinite bus with
voltage of 1 pu. If the transfer reactance
is 0.5 pu, the steady state power limit is
(1) 1.1 pu
(2) 0.55 pu
(3) 2.2 pu
(4) 2.6 pu
22) Tick out the correct statement.
(1) The higher the initial load, the
larger the critical clearing angle
(2) The higher the initial load, the lower
the critical clearing angle
(3) The initial load has nothing to do
with the critical clearing angle
(4) The higher the operating time of the
circuit breaker, the larger will be
the critical clearing angle
23) The incremental fuel cost for two
generating unit are given by
IC1 = 25 + 0.2Pg1, IC2 = 32 + 0.2Pg2,
wehre Pg1 & Pg2 are real power generated
by the units in MW. The economic
allocation for a total load of 250 MW.
Neglecting transmission loss is given by
(1) Pg1 = 140.25 MW, Pg2 = 109.75 MW
(2) Pg1 = 109.75 MW, Pg2 = 140.25 MW
(3) Pg1 = Pg2 = 125 MW
(4) Pg1 = 100 MW, Pg2 = 150 MW
222 (12 – A )
24. «²µÀÖ ¸À«ÄÃPÀgÀt S3 + 14S2 + 56S + K = 0 EgÀĪÀ ªÀåªÀ¸ÉÜ ¹ÜgÀªÁVgÀ¨ÉÃPÁzÀgÉ
(1) 0 < K < 784
(2) 1 < K < 64
(3) 10 > K > 660
(4) ªÉÄð£À AiÀiÁªÀÅzÀÆ C®è
25. F ¸ÀAeÉÕAiÀÄ£ÀÄß ªÁ» £ÀPÁ±ÉAiÀÄ°è UÀªÀĤ¹. EzÀgÀ°è »£ÀÄßtÂPÉAiÀÄ JµÀÄÖ ¥ÀxÀUÀ¼À£ÀÄß UÀÄgÀÄw¸À§ºÀÄzÀÄ.
(1) 6
(2) 8
(3) 10
(4) 12
26. KPÀvÀAwUÉ UËæAqï zÉÆõÀ JAzÀgÉ
(1) ¥ÁæªÀ¸ÉÜ R ªÀÄvÀÄÛ UËæAqï £ÀqÀÄªÉ zÉÆõÀ
(2) ¥ÁæªÀ¸ÉÜ Y ªÀÄvÀÄÛ UËæAqï £ÀqÀÄªÉ zÉÆõÀ
(3) ¥ÁæªÀ¸ÉÜ B ªÀÄvÀÄÛ UËæAqï £ÀqÀÄªÉ zÉÆõÀ
(4) AiÀiÁªÀÅzÁzÀgÉÆAzÀÄ ¥ÁæªÀ¸ÉÜ ªÀÄvÀÄÛ UËæAqï £ÀqÀÄªÉ zÉÆõÀ
27. ¸ÁÜ£À ¨É¸ÀÄUÉ ¥ÀæQæAiÉÄ ªÀÄÆ®¨sÀÆvÀªÁV EzÀ£ÀÄß CªÀ®A©¹zÉ.
(1) GµÀÚ GvÁàzÀ£É
(2) ¥sÉÆÃfðAUï MvÀÛqÀ C£Àé¬ÄPÉ
(3) (1) ªÀÄvÀÄÛ (2) JgÀqÀÆ
(4) N«ÄPï ¤gÉÆÃzsÀvÉ
28. MAzÀÄ ªÉÄïÉäöÊ£À¯ÁèzÀ «zÀÄåvï ¨É¼ÀQ¤AzÁUÀĪÀ ¢Ã¦ÛAiÀÄÄ zÀÆgÀ (d) §zÀ¯ÁzÀAvɯÁè EzÀPÀÌ£ÀÄUÀÄtªÁV
(1) 1
d2
(2) 1
d
(3) d
(4) d2
29. JgÀqÀÄ vÀAwUÀ¼À «zÀÄå¤ßgÉÆÃzsÀªÀÅ ¸ÀgÀtÂAiÀÄ°è
eÉÆÃr¹zÁUÀ 25 Ω ªÀÄvÀÄÛ ¸ÀªÀiÁAvÀgÀªÁV
eÉÆÃr¹zÁUÀ 6 Ω. ¥Àæw vÀAwAiÀÄ
«zÀÄå¤ßgÉÆÃzsÀªÀÅ
(1) 5 Ω, 10 Ω
(2) 10 Ω, 20 Ω
(3) 10 Ω, 15 Ω
(4) 20 Ω, 30 Ω
222 (13 – A )
24) A system with characteristic equation
S3 + 14S2 + 56S + K = 0 will be stable if
(1) 0 < K < 784
(2) 1 < K < 64
(3) 10 > K > 660
(4) None of the above
25) Consider the following signal flow graph :
How many feedback paths can be
identified ?
(1) Six
(2) Eight
(3) Ten
(4) Twelve
26) A Single line to ground fault means
(1) A fault between phase R and
Ground
(2) A fault between phase Y and
Ground
(3) A fault between phase B and
Ground
(4) A fault between any one phase and
ground
27) Spot welding process basically depends on
(1) Generation of heat
(2) Application of forging pressure
(3) Both (1) and (2)
(4) Ohmic resistance
28) The illumination at a surface due to a
source of light place at a distance d from
the surface varies as
(1) 1
d2
(2) 1
d
(3) d
(4) d2
29) The resistance of two wires is 25 Ω, when
connected in series and 6 Ω when
connected in parallel. The resistance of
each wire is
(1) 5 Ω, 10 Ω
(2) 10 Ω, 20 Ω
(3) 10 Ω, 15 Ω
(4) 20 Ω, 30 Ω
222 (14 – A )
30. MAzÀÄ 400 V, 10 kW 3- -¥ÁæªÀ¸ÉÜ, 6-¥ÉÆïï, 50 c/s ¥ÉæÃgÀPÀ ªÉÆÃlgï EAzsÀ£À ¯ÉÆÃqï£À°è NqÀĪÀ ¥ÀÆtð ªÉÃUÀ
(1) 900 & 1000 r.p.m £ÀqÀĪÉ
(2) 100 & 1500 r.p.m £ÀqÀĪÉ
(3) 1500 & 2000 r.p.m £ÀqÀĪÉ
(4) 2000 r.p.m ªÉÄîàlÄÖ
31. vÉgÉzÀ ®Æ¥ï ¤AiÀÄAvÀæt ªÀåªÀ¸ÉÜAiÀÄ°è F CA±ÀUÀ½gÀĪÀÅ¢®è.
(1) PÀrªÉÄ ªÉZÀÑ
(2) ¥ÀæPÀëħÞvɬÄAzÀ zÉÆõÀUÀ¼ÀÄAmÁUÀÄvÀÛzÉ
(3) gÀZÀ£É ¸ÀgÀ¼À ºÁUÀÆ ¸ÀÄ®¨sÀ ¤ªÀðºÀuÉ
(4) ¤UÀðvÀzÀ UÀÄtªÀÄlÖ PÁAiÀÄÄÝPÉƼÀî®Ä ªÀÄgÀÄPÀæªÀiÁAPÀzÀ CUÀvÀå«®è
32. ¥ÀAiÀiÁðAiÀÄ «zÀÄåvÀàçªÁºÀªÀ£ÀÄß ªÀiÁ¥À£À ªÀiÁqÀĪÀ ¸ÁzsÀ£À
(1) ZÀ°¸ÀĪÀ PÀ©ât «PÀµÀðt ªÀiÁzÀj ªÉÇïïÖ«ÄÃlgï
(2) ±Á±ÀévÀ PÁAvÀ ¨É¼ÀQ£À D«ÄäÃlgï
(3) ¸ÁÜ¬Ä «zÀÄåvï ªÉÇïïÖ «ÄÃlgï
(4) ¥ÉæÃgÀuÁ D«ÄäÃlgï
33. AiÀiÁªÀ G¥ÀPÀgÀtªÀ£ÀÄß ¥ÀAiÀiÁðAiÀÄ ºÁUÀÆ £ÉÃgÀ «zÀÄåvïUÀ¼ÉgÀqÀgÀ®Æè §¼ÀPÉ ªÀiÁqÀ¯ÁUÀzÀÄ ?
(1) ¥ÉæÃgÀPÀ ªÀiÁzÀj
(2) «zÀÄåvï UÀw²Ã® ªÀiÁzÀj
(3) ¸ÁÜ¬Ä «zÀÄåvï ªÀiÁzÀj
(4) ZÀ°¸ÀĪÀ PÀ©ât ªÀiÁzÀj
34. CzsÀð vÀgÀAUÀ ¸ÀÄzsÁgÀPÀzÀ UÀjµÀ× ¸ÁªÀÄxÀåðªÀÅ
(1) 50%
(2) 33.33%
(3) 40.6%
(4) 68%
35. NPN mÁæ¤ìlj£À°è ¸ÀAUÁæºÀPÀªÀÅ »ªÀÄÄäR M®ÄªÉÄAiÀÄzÁzÀgÉ GvÀìdðPÀ ¸ÀA¢üAiÀÄÄ ªÀÄĪÀÄÄäR M®ÄªÉÄAiÀÄzÁzÁUÀ mÁæ¤ìlgï PÁAiÀiÁðZÀgÀuÉAiÀÄÄ
(1) ¸ÀQæAiÀÄ ¥ÀæzÉñÀ ªÁå¦ÛAiÀÄ°è
(2) vÀqÉ ¥ÀæzÉñÀ (PÀmï D¥sï)
(3) ¥ÀAiÀiÁð¥ÀÛ ¥ÀæzÉñÀ (¸ÁåZÀÄgÉõÀ£ï)
(4) E£ïªÀmÉðqï ¥ÀæzÉñÀ
36. ¥Àæ¸ÀgÀt vÀAwAiÀÄ ªÉÄÃ®Ä ¸ÀjPÉ ªÀiÁqÀĪÀÅzÀPÉÌ PÁgÀt
(1) ¥Àæ¸ÀgÀt «zÀÄåvï £ÀµÀÖ vÀ¦à¸À®Ä (2) ¹Ì£ï¥ÀjuÁªÀÄ vÀ¦à¸À®Ä (3) ªÉÇïÉÖÃeï E½PÉ ¸ÀjzÀÆV¸À®Ä (4) PÀgÉÆãÁ vÀVθÀ®Ä
37. jAiÀiÁQÖªï ¥ÀªÀgï JAzÀgÉ
(1) ±ÀQÛ ªÀUÁðªÀuÉ zÀgÀ
(2) DgïJªÀiïJ¸ï ªÉÇïïÖ ªÀÄvÀÄÛ r.m.s. £À «zÀÄåvï ¥ÀæªÁºÀzÀ PÁéqÉæÃZÀgï CA±ÀzÀ UÀÄt®§Þ
(3) Dgï.JªÀiï.J¸ï ªÉÇïïÖ ªÀÄvÀÄÛ Dgï.JªÀiï.J¸ï. «zÀÄåvï ¥ÀæªÁºÀzÀ UÀÄt®§Þ
(4) Dgï.JªÀiï.J¸ï. ªÉÇïïÖ ªÀÄvÀÄÛ Dgï.JªÀiï.J¸ï. «zÀÄåvï ¥ÀæªÁºÀzÀ ºÀAvÀzÀ WÀlPÀUÀ¼À UÀÄt®§Þ
222 (15 – A )
30) A 400 V, 10 kW, 3-phase, 6-pole, 50 c/s
induction motor is expected to run at fuel
load
(1) Between 900 & 1000 r.p.m
(2) Between 100 & 1500 r.p.m
(3) Between 1500 & 2000 r.p.m
(4) Above 2000 r.p.m
31) Open loop control system does not have
the following features
(1) Less expensive
(2) Disturbances cause errors
(3) Construction is simple and easy for
maintenance
(4) To maintain the required quality in
the out put, recalibration is not
required.
32) Alternating current can be measured by
(1) Moving iron repulsion type volt
meter
(2) Permanent magnet light ammeter
(3) Electrostatic voltmeter
(4) Induction ammeter
33) Which instrument cannot be used for
both AC and DC ?
(1) Induction type
(2) Electrodynamic type
(3) Electrostatic type
(4) Moving iron type
34) The maximum efficiency of a half wave
rectifier is
(1) 50%
(2) 33.33%
(3) 40.6%
(4) 68%
35) In a NPN transistor, when collector
junction is reversed based and emitter
junction is forward biased the transistor
will operate is
(1) Active region
(2) Cut off region
(3) Saturation region
(4) Inverted region
36) Transposition of transmission line is done
to
(1) Reduce line losses
(2) Reduce skin effect
(3) Balance line voltage drop
(4) Reduce corona
37) Reactive power is
(1) Rate of energy transfer
(2) The product of r.m.s. volt and
quadrature component of r.m.s.
current
(3) The product of r.m.s. volt and r.m.s.
current
(4) The product of r.m.s. volt and in
phase component of r.m.s. current
222 (16 – A )
38. ¢ÃWÀð ¥Àæ¸ÀgÀt vÀAwAiÀÄ°è AiÀiÁªÀ ¯ÉÆÃqï EgÀ¢zÁÝUÀ
(1) ¹éÃPÁgÀPÀ CAvÀå ªÉÇïÉÖÃdÄ, PÀ½¸ÀĪÀ PÉÆ£É ªÉÇïÉÖÃfVAvÀ PÀrªÉÄ
(2) PÀ½¸ÀĪÀ PÉÆ£É ªÉÇïÉÖÃeï, ¹éÃPÁgÀzÀ PÉÆ£É ªÉÇïÉÖÃfVAvÀ PÀrªÉÄ
(3) ¹éÃPÁgÀPÀ CAvÀå ªÉÇïÉÖÃdÄ, PÀ½¸ÀĪÀ PÉÆ£É ªÉÇïÉÖÃfUÉ ¸ÀªÀĪÁVzÉ.
(4) F AiÀiÁªÀŪÀÇ C®è
39. KPÀvÁ «zÀÄåzÀA±ÀzÀ°è MAzÀÄ ¥ÀAiÀiÁðAiÀÄPÀªÀÅ ¸ÀAvÀÄ°vÀ ¯ÉÆÃqï£ÀÄß ¥ÀÆgÉʸÀĪÁUÀ, vÀAw ªÉÇïÉÖÃeï ªÀÄvÀÄÛ vÀAw «zÀÄåvï £ÀqÀÄªÉ EgÀĪÀ ¥ÁæªÀ¸ÉÜ PÉÆãÀªÀÅ
(1) 900
(2) 600
(3) 300
(4) 00
40. ¹APÀæ£À¸ï ªÉĶ¤£Àß°è GvÉÛÃd£À PÀrªÉÄ ¹ÜwAiÀÄ°èzÉ. CzÀÄ ¯ÁåVAUï ªÁgïì C£ÀÄß vÉUÉzÀÄPÉƼÀÄîvÀÛzÉ. CzÀÄ ºÁUÉ D¥ÀgÉÃlgï DzÁUÀ
(1) ¹APÀæ£À¸ï ªÉÆÃlgÀÄ
(2) ¹APÀæ£À¸ï GvÁàzÀPÀ
(3) F JgÀqÀÆ
(4) F AiÀiÁªÀŪÀÇ C®è
41. GvÁàzÀPÀ ¸ÁܪÀgÀzÀ°è MAzÀÄ C¢üPÀ ºÀÆrPÉ ¨É¯É ªÀÄvÀÄÛ PÀrªÉÄ PÁAiÀiÁðZÀgÀuÉ ªÉZÀѪÀÅ ¸ÁªÀiÁ£ÀåªÁV DUÀĪÀÅzÀÄ
(1) ¦ÃPï ¯ÉÆqï ªÀåªÀ¸ÉÜ
(2) ¨Éøï¯ÉÆÃqï ªÀåªÀ¸ÉÜ
(3) ªÀÄzsÀåªÀÄ ¯ÉÆÃqï ªÀåªÀ¸ÉÜ
(4) F AiÀiÁªÀŪÀÇ C®è
42. PÉÆgÉÆãÁ ¥ÀjuÁªÀĪÀ£ÀÄß vÀVθÀ®Ä ¸ÁªÀiÁ£ÀåªÁV
(1) ªÁºÀPÀUÀ¼À CAvÀgÀ vÀVθÀ¯ÁUÀĪÀÅzÀÄ
(2) ªÁºÀPÀzÀ ªÁå¸ÀªÀ£ÀÄß vÀVθÀ¯ÁUÀĪÀÅzÀÄ
(3) PÀAvÉAiÀiÁV ªÁºÀPÀUÀ¼À£ÀÄß G¥ÀAiÉÆÃV¸À¯ÁUÀĪÀÅzÀÄ
(4) ²µÀÖ (¸ÁÖçAqÉqï) ªÁºÀPÀUÀ¼À£ÀÄß G¥ÀAiÉÆÃV¸À¯ÁUÀĪÀÅzÀÄ.
43. UÁ½AiÀÄ qÉÊ-E¯ÉQÖçPï ¸ÁªÀÄxÀåðªÀÅ ¸ÁªÀiÁ£Àå ¸ÀAzÀ¨sÀðzÀ°è ¸ÀĪÀiÁgÀÄ
(1) 30 kV/cm
(2) 100 kV/cm
(3) 150 kV/cm
(4) 200 kV/cm
44. ¸ÀgÀtÂAiÀÄ zsÁgÀPÀUÀ¼À£ÀÄß «vÀgÀPÀ vÀAwUÀ¼À°è §¼ÀPÉ ªÀiÁqÀĪÀÅzÀÄ
(1) jAiÀiÁQÖªï «zÀÄåvï ¥ÀæªÁºÀ ¸ÀjzÀÆVPÉ
(2) ¹éÃPÁgÀ CAvÀå ªÉÇïÉÖÃeï C£ÀÄß ºÀUÀÄgÀ ¯ÉÆÃrAUï ¸ÀAzÀ¨sÀðzÀ°è vÀVθÀ®Ä
(3) ªÉÇïÉÖÃeï E½PÉ vÀVθÀ®Ä
(4) vÀAw ¥Àæ¸ÀgÀt £ÀµÀÖ vÀVθÀ®Ä
45. §ºÀÄvÉÃPÀ ºÀ¨É l¨ÉÊð£ÀÄ ¥ÀAiÀiÁðAiÀÄPÀUÀ¼À ¸ÀÄvÀÄÛ«PÉAiÀÄÄ EgÀĪÀŪÀÅ
(1) JgÀqÀÄ ¥ÉÆïïUÀ½UÁV
(2) 10 – 20 ¥ÉÆïïUÀ½UÁV
(3) 20 – 30 ¥ÉÆïïUÀ½UÁV
(4) 6 ¥ÉÆïïUÀ½UÁV
222 (17 – A )
38) In a long transmission line under no load
condition
(1) Receiving end voltage is less than
sending end voltage
(2) Sending end voltage is less than
receving end voltage
(3) Receiving end voltage equally
sending end voltage
(4) None of these
39) When an alternator is delivering a
balanced load at unity power factor,
phase angle between line voltage and line
current is
(1) 900
(2) 600
(3) 300
(4) 00
40) If synchronous machine is under excited
it takes lagging VArs from a system when
it is operated as a
(1) Synchronous motor
(2) Synchronous generator
(3) Both of the above two
(4) None of the above
41) A generating station which has a high
investment cost and low operating cost is
casually operated as
(1) Peak load station
(2) Base load station
(3) Medium load station
(4) None of the above
42) To reduce corona effect usually
(1) The distance between the conductor
is reduced
(2) The conductor diameter is reduced
(3) Bundled conductors are used
(4) Stranded conductor are used
43) The dielectric strength of air under
normal condition is around
(1) 30 kV/cm
(2) 100 kV/cm
(3) 150 kV/cm
(4) 200 kV/cm
44) Series capacitor can be used in
distribution lines
(1) To provide reactive power
compensation
(2) To reduce the receiving end voltage
under light loading condition
(3) To reduce the voltage drop
(4) To reduce line losses
45) Most of the steam turbine alternators are
wound for
(1) Two poles
(2) Ten to twenty poles
(3) Twenty to thirty poles
(4) Six poles
222 (18 – A )
46. NªÀgï ºÉqï ¥Àæ¸ÀgÀt vÀAwUÀ¼À vÁ¥À ºÉZÀѼÀ¢AzÀ
(1) MvÀÄÛ ºÁUÀÆ GzÀÝ ºÉZÀѼÀ
(2) MvÀÄÛ ºÁUÀÆ GzÀÝ vÀVÎPÉ
(3) MvÀÄÛ vÀVÎPÉ DzÀgÉ GzÀÝ ºÉZÀÄÑ
(4) F AiÀiÁªÀŪÀÇ C®è
47. MAzÀÄ £ÀÆåQèAiÀÄgï «zÀÄåvï ¸ÁܪÀgÀzÀ°è ªÀiÁqÀgÉÃlgïUÀ¼À£ÀÄß EnÖgÀĪÀÅzÀÄ F GzÉÝñÀPÁÌV
(1) ¤Ãj£À E£ï¯Émï ºÀjªÀ£ÀÄß ¤AiÀÄAwæ¸À®Ä
(2) jAiÀiÁPÀÖgïUÉ ¨ÉÃPÁzÀ £ÀÆåQèAiÀÄgï EAzsÀ£ÀzÀ ªÉÆvÀÛªÀ£ÀÄß ¤AiÀÄAwæ¸À®Ä
(3) £ÀÆåmÁæ£ÀÄUÀ¼À£ÀÄß ¤zsÁ£ÀUÀwAiÀÄ zÁV¸ÀĪÀÅzÀjAzÀ £ÀÆåQèAiÀÄgï ¸À«Ää¼À£ÀªÀ£ÀÄß ¤AiÀÄAwæ¸À®Ä
(4) l¨ÉÊð£ïUÉ ºÀjAiÀÄÄ«PÉAiÀÄ£ÀÄß ¤AiÀÄAwæ¸À®Ä
48. PÀrªÉÄ ¯ÉÊ£ï zÉÆõÀzÀ §ºÀÄ ¸ÀÆPÀÛ C.B. ¹éaAUï ¤gÉÆÃzsÀPÀ E°èzÉ
(1) UÁ½ ¨Áè¸ïÖ C.B.
(2) M.O.C.B.
(3) SF6 C.B.
(4) F AiÀiÁªÀŪÀÇ C®è
49. ¥ÉæÃgÀPÀ GvÁàzÀPÀUÀ¼ÀÄ F ¹è¥ïUÀ¼À £ÀqÀÄªÉ PÁAiÀÄð¤ªÀð»¸ÀÄvÀÛªÉ
(1) 1 < s < 2
(2) 0.1 < s < 1.0
(3) s < 0
(4) F AiÀiÁªÀŪÀÇ C®è
50. §PÉÆïïÓ j¯É G¥ÀAiÉÆÃUÀªÁUÀĪÀÅzÀÄ
(1) ¥ÀjªÀvÀðPÀ DAvÀjPÀ zÉÆõÀUÀ½AzÀ ºÁ¤AiÀiÁUÀĪÀÅzÀ£ÀÄß vÀ¦à¸À®Ä
(2) ¥ÀjªÀvÀðPÀPÉÌ ¨ÁºÀå ªÀÄvÀÄÛ DAvÀjPÀ zÉÆõÀUÀ½AzÀ ºÁ¤AiÀiÁUÀĪÀÅzÀ£ÀÄß vÀ¦à¸À®Ä
(3) ¥ÀjªÀvÀðPÀPÉÌ ¨ÁºÀå ºÁ¤ vÀ¦à¸À®Ä
(4) F AiÀiÁªÀŪÀÇ C®è
51. ¸ÀªÀiÁAvÀgÀ ¥sÀ®PÀ zsÁgÀPÀzÀ°è UÁ½AiÀÄÄ qÉÊJ¯ÉQÖçPï DVzÀÄÝ, CzÀ£ÀÄß «zÀÄåzÁªÉñÀUÉƽ¹ «zÀÄåvï ¥ÀÆgÉÊPÉ ¤°è¹zÁUÀ ¥sÀ®PÀUÀ¼À £ÀqÀÄªÉ §® J¥sï EzÉ. zsÁgÀPÀªÀ£ÀÄß FUÀ qÉÊ J¯ÉQÖçPï ¹ÜgÁAPÀ E EgÀĪÀ zÀæªÀ qÉÊ J¯ÉQÖçPï£À°è ªÀÄļÀÄV¹zÀgÉ ¥sÀ®PÀUÀ¼À £ÀqÀĪÀt §®
(1) E2F
(2) EF
(3) F/E
(4) F
52. Dgï.J¯ï. «zÀÄå£ÀäAqÀ® ¹éZï ªÀiÁrzÁUÀ, £ÉÃgÀ«zÀÄåvï, C£ÀÄß V ªÉÇïÉÖÃeï£À°è ¥ÀÆgÉʹzÁUÀ «zÀÄåvï ¥ÀæªÁºÀªÀÅ
(1) 𝑖(𝑡) =𝑉
𝑅(1 − 𝑒
−𝑅
𝐿𝑡)
(2) 𝑖(𝑡) =𝑉
𝑅(1 + 𝑒
𝑅
𝐿𝑡)
(3) 𝑖(𝑡) =𝑉
𝑅(1 − 𝑒
𝑅
𝐿𝑡)
(4) 𝑖(𝑡) =𝑉
𝑅(1 + 𝑒−𝑡)
222 (19 – A )
46) Increase in temperature in over head
transmission lines causes
(1) Increases in stress & length
(2) Decrease in stress & length
(3) Decrease in stress but increase in
length
(4) None of the above
47) The purpose of moderator in a nuclear
power plant is to
(1) Control flow of water inlet
(2) Control the amount of nuclear fuel
is to the reactor
(3) Control nuclear fusion rate by
slowing down the neutrons
(4) Control the steam flow to the
turbine
48) The most suitable C.B. for short line fault
without switching resister is
(1) Air blast C.B.
(2) M.O.C.B.
(3) SF6 C.B.
(4) None of the above
49) Induction generator works between slip
(1) 1 < s < 2
(2) 0.1 < s < 1.0
(3) s < 0
(4) None of the above
50) Buchholz relay is used for
(1) Protection of transformer against all
internal fault
(2) Tranformer protection against both
internal and external faults
(3) Protection of transformer against all
external faults
(4) None of the above
51) A parallel plate capacitor with air as
dielectric is charged and then
disconnected from the supply. The force
between the plates is F. if the capacitor is
now immersed in a liquid dielectric of
dielectric constant, ‘E’ The force between
the plates will be_____
(1) E2F
(2) EF
(3) F/E
(4) F
52) When an RL circuit is switched on across
a DC supply of V volts, the expression for
current is
(1) 𝑖(𝑡) =𝑉
𝑅(1 − 𝑒
−𝑅
𝐿𝑡)
(2) 𝑖(𝑡) =𝑉
𝑅(1 + 𝑒
𝑅
𝐿𝑡)
(3) 𝑖(𝑡) =𝑉
𝑅(1 − 𝑒
𝑅
𝐿𝑡)
(4) 𝑖(𝑡) =𝑉
𝑅(1 + 𝑒−𝑡)
222 (20 – A )
53. 𝑖(𝑡) = 𝐾𝑡𝑒−𝛼𝑡 AiÀÄÄ eÁ®zÀ gɸÁà£ïì DVzÁÝUÀ
𝑡 ≥ 𝑂, 𝛼 £ÉÊd zsÀ£À ¸ÀASÉåAiÀiÁzÁUÀ i(t)
UÀjµÀתÁUÀ ¨ÉÃPÁzÀgÉ ‘t’ AiÀÄ ¨É¯ÉAiÀÄÄ
(1) α
(2) 2 α
(3) 1
α
(4) α2
54. 220 V, 50 Hz, 4-¥ÉÆïï, ªÀÄÆgÀÄ ¥ÁæªÀ¸ÉÜAiÀÄ EAqÀPÀë£ï ªÉÆÃmÁgÀÄ ¥ÀÆtð ¯ÉÆÃqï ªÉÃUÀªÁzÀ 1450 rpm £À°è ¸ÁVzÉ. ªÉÆÃlgï DªÀvÁðAPÀ
(1) 1.65 Hz
(2) 2.5 Hz
(3) 0.35 Hz
(4) 50 Hz
55. DzÀ±Àð ¥ÀjªÀvÀðPÀªÀÅ 150 ¸ÀÄvÀÄÛ ¥ÁæxÀ«ÄPÀ ªÀÄvÀÄÛ
750 ¸ÀÄvÀÄÛ ¢éwÃAiÀÄPÀ EgÀĪÀAvÀºÀÄzÀÄ. ¥ÁæxÀ«ÄPÀ
ªÀ£ÀÄß 240 V, 50 Hz DPÀgÀPÉÌ ¸ÀA¥ÀQð¹zÉ.
¢éwÃAiÀÄPÀ 4 A ¯ÉÆqï C£ÀÄß ¯ÁåVAUï ¦.J¥sï.
0.8 £À°è ¥ÀÆgÉʸÀÄvÀÛzÉ. ¥ÁæxÀ«ÄPÀ PÀgÉAlÄ
(1) 10 A
(2) 20 A
(3) 30 A
(4) 2 A
56. CzsÀð ¤AiÀÄAwævÀ KPÀ ¥ÁæªÀ¸ÉÜAiÀÄ ¸ÉÃvÀÄ
¥ÀjªÀvÀðPÀªÀÅ GvÉÛÃfvÀ r.¹. ªÉÆÃljUÉ
¥ÀævÉåÃPÀªÁV ¥ÀÆgÉʸÀÄvÀÛzÉ. ªÉÇïÉÖÃeï 240 V,
α = 90° Rα = 6 ohm ªÀÄvÀÄÛ I = 2 A EzÀÝgÉ
¨ÁåPï «¨sÀªÁAvÀgÀ (e.m.f.)
(1) 120 V
(2) 240 V
(3) 132 V
(4) 228 V
57. DPÀgÀ EAqÀPÉÖ£ïì£À ¥ÀjuÁªÀÄ 3-¥ÁæªÀ¸ÉÜ J.¹.r.¹.
¥ÀjªÀvÀðPÀzÀ ªÉÄð£À ¤UÀðvÀ ªÉÇïÉÖÃf£À ªÉÄïÉ
»ÃUÉ
(1) ¤UÀðvÀ ªÉÇïÉÖÃf£À ºÉZÀѼÀ
(2) ¤UÀðvÀ ªÉÇïÉÖÃeï vÀVÎPÉ
(3) ¤UÀðvÀ ªÉÇïÉÖÃf£À°è §zÀ¯ÁªÀuÉ E®è
(4) F AiÀiÁªÀŪÀÇ C®è
58. xÉÊj¸ÀÖgï C£ÀÄß G¢ÝÃ¥À£À ÊÜÞvÜ ¨ÉÃPÁzÀgÉ 𝑑𝑣
𝑑𝑡 = 200 v/μs . CzÀgÀ zsÁgÀPÀvÉAiÀÄ
«zÀÄåvÀàçªÁºÀªÀÇ eÉÆÃqÀuÉAiÀÄ°è 10 mA EzÉ.
¸ÀªÉvÀ ¥ÀzÀgÀzÀ ¸ÀªÀiÁ£ÀPÀ zsÁgÀPÀvÉ
(1) 10 μF
(2) 2 μF
(3) 20 μF
(4) 10 F
222 (21 – A )
53) The response of a network, 𝑖(𝑡) = 𝐾𝑡𝑒−𝛼𝑡
for 𝑡 ≥ 𝑂, where α is real positive. The
value of ‘t’ at which the i(t) will become
maxiumum is
(1) α
(2) 2 α
(3) 1
α
(4) α2
54) A 220 V, 50 Hz, 4-pole, three phase
induction motor has a full load speed of
1450 rpm. The rotor frequency is
(1) 1.65 Hz
(2) 2.5 Hz
(3) 0.35 Hz
(4) 50 Hz
55) An ideal transformer has a 150 turn
primary and 750 turn secondary. The
primary is connected to a 240 V, 50 Hz
source. The secondary winding supplies a
load of 4 A at a lagging p.f. of 0.8. Its
current in the primary is
(1) 10 A
(2) 20 A
(3) 30 A
(4) 2 A
56) A half controlled single phase bridge
converter feeds a sperately exicited DC
motor. Input voltage is 240 V, α = 900
Rα = 6 Ohm and I = 2 A.The back e.m.f. is
(1) 120 V
(2) 240 V
(3) 132 V
(4) 228 V
57) The effect of source inductance on the
output voltage of a 3-phase AC-DC
converter is
(1) Increase in the output voltage
(2) Decrease in the output voltage
(3) No change in the output voltage
(4) None of the above
58) A thyristor can be triggered if 𝑑𝑣
𝑑𝑡 is
200 v/μs. If the capacitive current flowing
through the junction is 10 mA. The
equivalent capacitance of depletion layer
is
(1) 10 μF
(2) 2 μF
(3) 20 μF
(4) 10 F
222 (22 – A )
59. ¥ÀjªÀvÀðPÀzÀ ¥ÁæxÀ«ÄPÀªÀ£ÀÄß ZËPÀ C¯É ªÉÇïÉÖÃeï DPÀgÀ¢AzÀ ±ÀQÛAiÀÄÄvÀUÉƽ¹zÉ. CzÀgÀ ¤UÀðvÀ ªÉÇïÉÖÃeï
(1) ¸ÉÊ£ï C¯É
(2) wæPÉÆäÃAiÀÄ C¯É
(3) «Är¯ï C¯É
(4) ZËPÀ C¯É
60. r.¹. AiÀÄAvÀæzÀ°è UÁ½AiÀÄ CAvÀzÀ GzÀÝ
KPÀgÀÆ¥ÀzÀ°ègÀzÉ EgÀ®Ä PÁgÀt
(1) ¸ÉÊ£ÀĸÁ¬Ä¯ï ªÉÄÊ£ï¦üïïØ ¥sÀèPïì ¥ÀqÉAiÀÄĪÀÅzÀÄ
(2) GvÀÛªÀÄ ±ÉÊvÀå£À ¥ÀqÉAiÀÄĪÀÅzÀÄ
(3) DªÉÄÃðZÀgï£À JªÀiï JªÀiï J¥sï£À ¥ÀjuÁªÀĪÀ£ÀÄß ¥ÀæzsÁ£À PÉëÃvÀæzÀ ªÉÄÃ¯É PÀ¤µÀ×UÉƽ¸ÀĪÀÅzÀÄ
(4) ¸ÉÊ£ÀĸÁ¬Äدï DªÉÄÃðZÀgï JªÀiï.JªÀiï.J¥sï. C¯É ¥ÀqÉAiÀÄĪÀÅzÀÄ
61. KPÀ¥ÁæªÀ¸ÉÜ ±ÀPÀÛ «ÄÃlgÀÄ 230 V ªÀÄvÀÄÛ 50 Hz
£À°è PÁAiÀÄð¤ªÀ𻹠20 A «zÀÄåvï ¯ÉÆÃqï
C£ÀÄß 2 UÀAmÉUÀ¼À PÁ® AiÀÄƤmï ¥ÀªÀgï
¥sÁåPÀÖgï£À°è ¤ÃrzÉ. D CªÀ¢üAiÀÄ°è «ÄÃlgï
1380 ¨Áj wgÀÄVzÉ. «ÄÃlgï ¹ÜgÁAPÀªÀÇ
(1) 695 rev/kWh
(2) 150 rev/kWh
(3) 0.15 rev/kWh
(4) 1
150 rev/kWh
62. ¹ÖçAUï ¹ÜgÁAPÀzÀ ¸ÁÜ¬Ä «zÀÄåvï ªÉÇïïÖ «ÄÃlgÀÄ «ÄÃlgÀÄ ¥ÀÆtð «ZÀ¯É£À 800 AiÀÄ£ÀÄß 0.2 kV ¤ÃrzÁUÀ ¤ÃrzÉ. zsÁgÀPÀvÉAiÀÄÄ KPÀgÀÆ¥ÀzÀ°è C¢üPÀUÉÆAqÀÄ 20 ¦üJ¥sï¤AzÀ 100 ¦J¥sïUÉ 800 AiÀÄ°è ±ÀÆ£Àå «ZÀ®£ÉAiÀÄ£ÀÄß vÉÆÃgÀÄvÀÛzÉ. 1.5 kV UÉ «ZÀ®£ÉAiÀÄÄ
(1) 200
(2) 300
(3) 450
(4) 600
63. qÉÊ J¯ÉQÖçPï ®ÜÐÜr ªÀÄvÀÄÛ ¥ÀªÀgï ¥sÁåPÀÖgï C£ÀÄß
C¼ÀvÉ ªÀiÁqÀ®Ä ________ C£ÀÄß G¥ÀAiÉÆÃV¸ÀĪÀÅzÀÄ.
(1) ªÀiÁåPïìªÉ¯ï ©æqïÓ
(2) ¸ÉÌÃjAUï ©æqïÓ
(3) «Ã£ï ©æqïÓ
(4) «Ãmï¸ÉÆÖÃ£ï ©æqïÓ
64. PÉÆÃgÉÆ£À ¥ÀjuÁªÀĪÀÅ PÀrªÉÄ AiÀiÁWÜáªÀÅzÀÄ
QænPÀ¯ï ªÉÇïÉÖÃeï C£ÀÄß ___________ ºÉZÀÄÑ ªÀiÁrzÁUÀ.
(1) zsÁgÀPÀUÀ¼À £ÀqÀÄ«£À CAvÀgÀªÀ£ÀÄß ºÉaѹzÁUÀ
(2) zsÁgÀPÀzÀ ªÁå¸ÀªÀ£ÀÄß ºÉaѹzÁUÀ
(3) ªÉÄð£À (1) ªÀÄvÀÄÛ (2) AiÀiÁªÀÅzÁzÀgÀÆ
(4) ªÉÄð£À AiÀiÁªÀÅzÀÄ C®è
222 (23 – A )
59) The primary of a transformer is energized
from a square wave voltage source. Its
output voltage will be
(1) Sine wave
(2) Triangular wave
(3) Pulsed wave
(4) Square wave
60) In DC machines, the air-gap length under
the poles is not kept uniform, so as to
(1) Obtain a sinusoidal main field flux
(2) Obtain better cooling
(3) Minimise the effect of armature
m.m.f on main field
(4) Obtain sinusoidal armature m.m.f
wave
61) A single phase energy meter is operating
on 230 V, 50 Hz supply with a load of
20 A for 2 hours at unity power factor.
The meter makes 1380 revolutions in that
period. The meter constant is
(1) 695 rev/kWh
(2) 150 rev/kWh
(3) 0.15 rev/kWh
(4) 1
150 rev/kWh
62) An electrostatic voltmeter with spring
constant gives a full scale deflection 800
when 0.2 kV is applied. The capacitance
increases uniformly with angular
deflection from 20 P.F. for zero defelection
to 100 P.F. for 800. The deflection for
1.5 kV will be
(1) 200
(2) 300
(3) 450
(4) 600
63) A bridge used for measurement of
dielectric loss and power factor is
(1) Maxwell’s bridge
(2) Schering bridge
(3) Wein bridge
(4) Wheatstone bridge
64) The effect of corona can be a reduced if
the critical voltage can be raised by
(1) Increasing the spacing between the
conductors
(2) Increasing the diameter of the
conductor
(3) Either (1) & (2)
(4) None of the above
222 (24 – A )
65. ¸ÀAeÁÕ ¥ÀæªÁºÀ £ÀPÁ±É avÀæ 1 gÀ°èzÉ. ªÀÄĪÀÄÄäR
¥ÀxÀUÀ¼ÀÄ (M) ªÀÄvÀÄÛ ¸ÀévÀAvÀæ ®Æ¥ïUÀ¼ÀÄ (P) F
£ÀPÁ±ÉUÉ
(1) M=4, P=4
(2) M=6, P=6
(3) M=6, P=4
(4) M=4, P=6
66. ¯ÁUï – ªÀiÁåVßlÆåqïUÀÆ MAzÀÄ ¤AiÀÄAvÀæt
ªÀåªÀ¸ÉÜAiÀÄ DªÀvÁðAPÀPÉÌ 0 dB CPÀëzÀ°è ¥ÀgÀ¸ÀàgÀ
bÉÃzÀ£À GAmÁzÀgÉ CzÀ£ÀÄß »ÃUÉ£ÀÄߪÀgÀÄ
(1) UÉÊ£ï PÁæ¸ï NªÀgï DªÀvÁðAPÀ
(2) ¥sÉøï PÁæ¸ï NªÀgï DªÀvÁðAPÀ
(3) C£ÀÄPÀgÀt DªÀvÁðAPÀ
(4) £ÉÊd DªÀvÁðAPÀ
67. F avÀæzÀ°è£À «zÀÄå£ÀäAqÀ®ªÀÅ MAzÀÄ
(1) CzsÀð C¯É ¢µÀÖPÀ
(2) ±ÀÈAUÀ ¥ÀvÉÛPÁgÀPÀ
(3) ¥ÀÆtð C¯É ¢µÀÖPÀ
(4) PÁèA¦AUï «zÀÄå£ÀäAqÀ®
68. IÄuÁvÀäPÀ ¥ÀæwgÉÆÃzsÀPÀzÀ ªÉʲµÀÖöåUÀ¼À£ÀÄß
¥ÀæzÀ²ð¸ÀĪÀÅzÀÄ
(1) vÁ¥À ¢Ã¦ÛAiÀÄ ¢Ã¥À
(2) «zÀÄåvï ¥ÀjªÀvÀðPÀ
(3) AiÀÄÄ.eÉ.n.
(4) ¸Àߧâgï ªÀÄAqÀ®
69. F PɼÀV£À AiÀiÁªÀ mÁæ¤ì ÀÖgïUÀ¼À£ÀÄß
J£ïºÁ£ïìªÉÄAmï ªÀiÁzÀjAiÀÄ°è
G¥ÀAiÉÆÃV¸À¯ÁUÀĪÀÅzÀÄ
(1) UJT
(2) MOSFET
(3) JFET
(4) NPN mÁæ¤ì¸ÀÖgï
70. MAzÀÄ ¥ÉÆæÃUÁæªÀiï 10 ªÉĪÀÄj ¯ÉÆPÉñÀ£ïUÀ¼À£ÀÄß
¤gÀAvÀgÀªÁV ºÁzÀÄ ºÉÆÃUÀÄvÀÛzÉ. CPU PÀrªÉÄ
¸ÀªÀÄAiÀÄ vÉUÉzÀÄPÉÆAqÀgÉ CqÉæ¹ìAUï ªÉÆÃqï
§¼ÀPÉAiÀiÁUÀĪÀÅzÀÄ ___________
(1) £ÉÃgÀ
(2) ¥ÀgÉÆÃPÀë £ÉÆÃAzÀtÂ
(3) PÀÆqÀ¯ÉÃ
(4) CAvÀUÀðvÀ
222 (25 – A )
65) A single flow graph is shown in figure
below. The number of forward paths (M)
and number of independent loops (P) for
this signal flow graph would be
(1) M=4, P=4
(2) M=6, P=6
(3) M=6, P=4
(4) M=4, P=6
66) The frequency at which the
log-magnitude versus frequency plot of a
control system intersects 0 dB axis is
known as
(1) gain cross over frequency
(2) phase cross over frequency
(3) resonant frequency
(4) natural frequency
67) The circuit shown in figure is a
(1) Half wave rectifier
(2) Peak detector
(3) Full wave rectifier
(4) Clamping circuit
68) Negative resistance characteristic is
exhibited by
(1) Incandescent lamp
(2) transformer
(3) UJT
(4) Snubber circuit
69) Which of the following transistors can be
used in enhancement type?
(1) UJT
(2) MOSFET
(3) JFET
(4) NPN transistor
70) A program access ten continuous memory
locations. The CPU will take less time if
the addressing mode used is
(1) direct
(2) Register indirect
(3) immediate
(4) implicit
222 (26 – A )
71. MAzÀÄ EA¦qÉ£ïì UÀÄt®PÀëtzÀ ¸ÀAªÀºÀ£À vÀAwAiÀÄÄ ±ÉæÃtÂUÀ¼À EA¦qÉ£ïì£ÉÆA¢VzÀÄÝ CzÀÄ 1 KPÀªÀiÁ£À GzÀÝPÉÌ Z/ohms ªÀÄvÀÄÛ MAzÀÄ KPÀªÀiÁ£ÀzÀ GzÀÝPÉÌ ±ÀAmï CrämÉ£ïì Y mhos EgÀĪÀÅzÀ£ÀÄß EzÀÄ ¤ÃqÀĪÀÅzÀÄ
(1) (𝑍 + 𝑌)2
(2) √𝑍
𝑌2
(3) √𝑍
𝑌
(4) √(𝑍
𝑌)2
72. 100 MVA, 11 kV gÉÃmÉqï£À 3 d£ÀgÉÃlgïUÀ¼ÀÄ
¥ÀæwAiÉÆAzÀÄ 0.15 pu EA¦ÃqÉ£ïìUÀ¼À£ÀÄß
ºÉÆA¢zÉ. EªÀÅ MAzÉà ¸ÁܪÀgÀzÀ°èzÀÄÝ EªÀÅUÀ¼À£ÀÄß
KPÀ ¸ÀªÀiÁ£ÀPÀ d£ÀgÉÃlgï¤AzÀ §zÀ°¹zÀ°è DUÀ
KPÀ ¸ÀªÀiÁ£ÀPÀ d£ÀgÉÃlgï£À ¥ÀjuÁªÀÄPÁj
EA¦qÉ£ïìªÀÅ
(1) 0.05 pu
(2) 0.15 pu
(3) 0.25 pu
(4) 0.45 pu
73. ªÀÄÆgÀÄ ¥ÁæªÀ¸ÉÜ ¹APÉÆæãÀ¸ï ªÉÆÃlgï MAzÀgÀ°è£À
IÄt (£ÉUÉnªï) ¥ÁæªÀ¸ÉÜ C£ÀÄPÀæªÀĪÀÅ
G½zÀÄPÉƼÀÄîªÀÅzÀÄ ªÉÆÃlgï »ÃVzÁÝUÀ
(1) PÀrªÉÄ sÁgÀ ºÉÃjzÁÝUÀ
(2) C¢üPÀ ¨sÁgÀ ºÉÃjzÁÝUÀ
(3) C¸ÀAvÀÄ°vÀ ªÉÇïÉÖÃeï
¥ÀÆgÉÊPÉAiÉÆA¢VzÁÝUÀ
(4) ªÉÄð£À AiÀiÁªÀÅzÀÆ C®è
74. 35 V ¥ÀÆgÉÊPÉAiÀÄ MAzÀÄ r¹AiÀÄ£ÀÄß ±ÉæÃtÂAiÀÄ°è
600 Ω gÉÆÃzsÀPÀzÀ CqÀØPÉÌ eÉÆÃr¸À¯ÁVzÉ MAzÀÄ
UÉÆwÛ®èzÀ gɹ¸ÀÖ£ïì£ÉÆA¢UÉ 1.2 kΩ gɹ¸ÀÖ£ïì G¼Àî
1 ªÉÇïïÖ«ÄÃlgï£ÀÄß 600 Ω gɹ¸ÀÖ£ïìUÉ
eÉÆÃr¸À¯ÁVzÀÄÝ, EzÀÄ 5 V AiÀÄ£ÀÄß NzÀÄvÀÛzÉ. DUÀ
UÉÆwÛgÀzÀ gɹ¸ÀÖ£ïìªÀÅ
(1) 50 Ω
(2) 1.7 kΩ
(3) 3.6 kΩ
(4) 2.4 kΩ
222 (27 – A )
71) The characteristic impedance of a
transmission line with series impedance
Z/ohms per unit length and shunt
admittance Y mhos per unit length is
given by
(1) (𝑍 + 𝑌)2
(2) √𝑍
𝑌2
(3) √𝑍
𝑌
(4) √(𝑍
𝑌)2
72) Three generator rated 100 MVA, 11 kV
have an impedance of 0.15 pu each. If in
the same plant, these generators are
replaced by a single equivalent generator
then the effective impedance of single
equivalent generator will be.
(1) 0.05 pu
(2) 0.15 pu
(3) 0.25 pu
(4) 0.45 pu
73) The negative phase sequence in a three
phase synchronous motor exists when the
motor is
(1) Under loaded
(2) Over loaded
(3) Supplied with unbalance voltage
(4) None of the above
74) A dc supply of 35 V is connected across
600 Ω resistance in series with an
unknown resistance. The voltmeter
having a resistance of 1.2 kΩ is connected
across 600 Ω resistance which reads 5 V.
Then the unknown resistance should be
(1) 50 Ω
(2) 1.7 kΩ
(3) 3.6 kΩ
(4) 2.4 kΩ
222 (28 – A )
75. F PɼÀV£À «zÀÄå£ïªÀÄAqÀ®zÀ°è£À DPÀgÀªÀÅ ¸ÉÊ£ÀĸÁAiÀÄدï. ªÉÇïÉÖÃeï E½ªÀÄÄRªÀ£ÀÄß DAiÀiÁ ©AzÀÄUÀ½UÉ ¸ÀA§A¢ü¹zÀAvÉ ¤ÃrzÀÄÝ, DUÀvÀ ªÉÇïÉÖÃeï
(1) 10 V
(2) 27 V
(3) 5 V
(4) 24 V
76. JgÀqÀÄ ¥ÉÆÃmïð eÁ®ªÀ£ÀÄß F ¸ÀA§AzsÀ¢AzÀ I1=2V1+V2, I2=2V1+3V2,
DUÀ Z12 AiÀÄÄ ¤gÀƦ¸À¯ÁVzÀÄÝ
(1) -2 Ω
(2) -1 Ω
(3) -½ Ω
(4) ¼ Ω
77. �� = 2𝑎𝑥 + 4𝑎𝑦 − 3𝑎𝑧 ªÀÄvÀÄÛ
�� = 𝑎𝑥 − 𝑎𝑦, DzÀgÉ �� ªÀÄvÀÄÛ �� UÀ¼À PÁæ¸ï UÀÄt®§Þ
(1) -3ax-3ay-6az
(2) -3ax+3ay-6az
(3) 3ax-3ay-6az
(4) 3ax+3ay-6az
78. “¸À¢±À PÉëÃvÀæ F £À ¸Àà±ÀðPÀ CA±ÀzÀ CªÀPÀ®PÀªÀÅ DªÀÈvÀ ¥ÀxÀ C AiÀÄ°èzÀÄÝ, EzÀÄ ªÉÄïÉäöʪÉÄð£À PÀ¯ïð£À ¸ÁªÀÄ£Àå PÁA¥ÉÆ£ÉAmï£À CªÀPÀ®PÀPÉÌ ¸ÀªÀĪÁVgÀÄvÀÛzÉ” JA§ ºÉýPÉ F ¥ÀæªÉÄÃAiÀÄzÀÄÝ
(1) UÁ¸ï
(2) ¸ÉÆÖÃPïì
(3) §AiÀiïÖ-¸ÁªÀmï
(4) DA¦AiÀÄgï
79. C®Æå«Ä¤AiÀĪÀiï£À°è 1.6 Mhz DªÀvÁðAPÀzÀ ¹Ì£ï D¼À ‘δ’ ªÀÅ σ = 38.2 ms/meter ªÀÄvÀÄÛ μr = 1 EzÁÝUÀ ______
(1) 64.4 μm
(2) 64.4 m
(3) 64.4 km
(4) 64.4 mm
80. vÀgÀAUÀªÀÅ 300 PÉÆãÀzÀ°è ¥ÀvÀ£ÀªÁV UÁ½¬ÄAzÀ mÉ¥sÁè£ï vÀ®Ä¦zÀ Er=2.1 ¥Àæ¸ÀgÀt PÉÆãÀªÀÅ
(1) 300
(2) 20.180
(3) 450
(4) 50.180
222 (29 – A )
75) The source in the circuit shown is
sinusoidal. The voltage drop across
various elements are given, the input
voltage is
(1) 10 V
(2) 27 V
(3) 5 V
(4) 24 V
76) A two port network is defined by the
relation I1=2V1+V2, I2=2V1+3V2, then Z12
is
(1) -2 Ω
(2) -1 Ω
(3) -½ Ω
(4) ¼ Ω
77) Given �� = 2𝑎𝑥 + 4𝑎𝑦 − 3𝑎𝑧 and �� = 𝑎𝑥 − 𝑎𝑦,
the cross product of �� 𝑎𝑛𝑑 �� is
(1) -3ax-3ay-6az
(2) -3ax+3ay-6az
(3) 3ax-3ay-6az
(4) 3ax+3ay-6az
78) “The integral of the tangential component
of a vector field ‘F’ around closed path ‘C’
is equal to the integral of the normal
component of the curl over surface” is the
statement of _____ theorem.
(1) Gauss’s
(2) Stoke’s
(3) Biot-Savart’s
(4) Ampere’s
79) The skin depth ‘δ’ at a frequency of
1.6 MHz in aluminium when
σ = 38.2 ms/meter and μr = 1 is _____
(1) 64.4 μm
(2) 64.4 m
(3) 64.4 km
(4) 64.4 mm
80) A wave is incident at an angle of 300 from
air to Teflon, Er = 2.1, the angle of
transmission is
(1) 300
(2) 20.180
(3) 450
(4) 50.180
222 (30 – A )
81. ¹ävï ¥ÀlªÀÅ EzÀgÀ ¯ÉPÁÌZÁgÀPÉÌ §¼ÀPÉ DUÀĪÀÅzÀÄ
(1) ªÀQæèsÀªÀ£À UÀÄuÁAPÀ
(2) ¥Àæw ¥sÀ®£À UÀÄuÁAPÀ
(3) ¥Àæ¸ÀgÀt UÀÄuÁAPÀ
(4) ¥ÀvÀ£À UÀÄuÁAPÀ
82. r¹ Êæᶣï£À°è ¹é£ï§£ïð£À ¥ÀjÃPÉë
(1) AiÀiÁªÀÅzÉà ¯ÉÆÃqïUÀ¼À £ÀµÀÖªÀ£ÀÄß ¯ÉPÀÌ
ªÀiÁqÀĪÀÅ¢®è ªÀÄvÀÄÛ vÁªÀÄæ £ÀµÀÖzÀ
ªÀiÁ¥À£À (measure) ªÀiÁqÀĪÀÅzÀÄ
(2) AiÀiÁªÀÅzÉà ¯ÉÆÃqïUÀ¼À £ÀµÀÖªÀ£ÀÄß ªÀiÁ¥À£À
ªÀiÁqÀĪÀÅ¢®è ªÀÄvÀÄÛ vÁªÀÄæ £ÀµÀÖzÀ
¯ÉPÀÌZÁgÀ (Calculation) ªÀiÁqÀĪÀÅzÀÄ
(3) ¯ÉÆÃqï £ÀµÀÖ ªÀÄvÀÄÛ vÁªÀÄæ £ÀµÀÖ JgÀqÀ£ÀÄß
¯ÉPÁÌZÁgÀ ªÀiÁqÀĪÀÅzÀÄ
(4) ¯ÉÆÃqï £ÀµÀÖ ªÀÄvÀÄÛ vÁªÀÄæ £ÀµÀÖ
JgÀqÀ£ÀÆß ªÀiÁ¥À£À ªÀiÁqÀĪÀÅzÀÄ
83. SCR £À C¢üPÀ ªÉÇïÉÖÃf£ÉÆA¢V£À ¥ÀAiÀiÁðAiÀÄPÀªÀÅ
(1) zÀħ𮠪ÉÇïÉÖÃeï ¤AiÀÄAvÀæt ªÀÄvÀÄÛ
C¢üPÀ ¹ÜgÀvÁ«Äw
(2) GvÀÛªÀÄ ªÉÇïÉÖÃeï ¤AiÀÄAvÀæt ªÀÄvÀÄÛ
C¢üPÀ ¹ÜgÀvÁ«Äw
(3) zÀħ𮠪ÉÇïÉÖÃeï ¤AiÀÄAvÀæt ªÀÄvÀÄÛ
PÀrªÉÄ ¹ÜgÀvÁ«Äw
(4) GvÀÛªÀÄ ªÉÇïÉÖÃeï ¤AiÀÄAvÀæt ªÀÄvÀÄÛ
PÀrªÉÄ ¹ÜgÀvÁ«Äw
84. ¹APÀæ£À¸ï AiÀÄAvÀæªÀ£ÀÄß ¥ÀªÀgï ¹¸ÀÖªÀiï §¸ï
¨ÁgïUÉ ¸ÀA¥ÀQð¹zÁUÀ GvÁàzÀPÀzÀ ZÁ®£É
PÉÊUÉÆArzÉ. AiÀÄAvÀæªÀÅ ªÉÆÃlgï£ÀAvÉ
D¥ÀgÉÃlgï DUÀ¨ÉÃPÁzÀgÉ
(1) wgÀÄUÀĪÀ ¢PÀÌ£ÀÄß «gÀÄzÀÞªÁV¸À¨ÉÃPÀÄ
(2) ¥ÁæªÀ¸ÉÜ C£ÀÄPÀæªÀĪÀ£ÀÄß §zÀ¯Á¬Ä¸À¨ÉÃPÀÄ
(3) PÉëÃvÀæ GvÉÛÃd£ÀªÀ£ÀÄß vÀVθÀ¨ÉÃPÀÄ
(4) AiÀiÁAwæPÀ DUÀvÀªÀÅ µÁ¥ïÖ£À £ÀµÀÖQÌAvÀ
PÀrªÉÄ EgÀ¨ÉÃPÀÄ
222 (31 – A )
81) Smith chart is used to calculate
(1) Refraction co-efficient
(2) Reflection co-efficient
(3) Transmission co-efficient
(4) Incident co-efficient
82) In Swinburne’s test of a DC machine
(1) No load losses are calculated and
copper losses are measured
(2) No load losses are measured and
copper losses are calculated
(3) Both the no load losses and copper
losses are calculated
(4) Both the no load losses and copper
losses are measured
83) An alternator with higher value of SCR
has
(1) Poor voltage regulation and higher
stability limit
(2) Better voltage regulation and higher
stability limit
(3) Poor voltage regulation and lower
stability limit
(4) Better voltage regulation and lower
stability limit
84) A synchronous machine connected to a
power system bus bar is operating as a
generator. To make the machine to
operate as motor
(1) Direction of rotation is to be
reversed
(2) Phase sequence is to be changed
(3) Field excitation is to be decreased
(4) Mechanical input is to be less than
the losses at the shaft
222 (32 – A )
85. C£Àé¬Ä¹zÀ ªÉÇïÉÖÃeï ¥ÀjªÀvÀðPÀªÉÇAzÀgÀ°è
50% C¢üPÀUÉÆArzÉ. DªÀvÁðAPÀªÀ£ÀÄß 50% PÉÌ
vÀVθÀ¯ÁVzÉ. (PÁAwÃAiÀÄ «zÀÄå£ÀAqÀ®
C¥ÀAiÀiÁð¥ÀÛ JAzÀÄ ¨sÁ«¹) PÉÆÃgï ¶ÜÉ P…Õ
¸ÁAzÀævÉAiÀÄ UÀjµÀ× ¨É¯É
(1) ªÀÄÆ® ¨É¯ÉVAvÀ ªÀÄÆgÀÄ ¥ÀlÄÖ §zÀ¯ÁªÀuÉ
(2) ªÀÄÆ®¨É¯ÉVAvÀ 1.5 ¥ÀlÄÖ §zÀ¯ÁªÀuÉ
(3) ªÀÄÆ® ¨É¯ÉVAvÀ 0.5 ¥ÀlÄÖ §zÀ¯ÁªÀuÉ
(4) ªÀÄÆ® ¨É¯ÉAiÀĵÉÖà G½AiÀÄĪÀÅzÀÄ
86. F ¯ÁfPï «zÀÄå£ÀäAqÀ®zÀ avÀæªÀÅ EzÀ£ÀÄß
¥Àæw¤¢ü¸ÀĪÀÅzÀÄ
(1) ¥ÀÆtð ¸ÀAPÀ®PÀ
(2) CgÉ ¸ÀAPÀ®PÀ
(3) CgÉ ªÀåªÀPÀ®PÀ
(4) §Æå°AiÀÄ£ï UÀÄuÁPÁgÀPÀ
87. ¥ÁæªÀ¸ÁÜ ¤AiÀÄAwævÀ ¸ÉÃvÀÄ ¢µÀ×zÀ°è ªÉÄîÄ
¸ÉÃ¥ÀðqÉ PÉÆãÀ ºÉZÀѼÀUÉÆAqÁUÀ ¤UÀðvÀ r.¹.
ªÉÇïÉÖÃeï
(1) vÀUÀÄÎvÀÛzÉ
(2) ºÉZÀÄÑvÀÛzÉ
(3) §zÀ¯ÁUÀzÀÄ
(4) ¯ÉÆÃqï ¥ÉæÃgÀuÉAiÀÄ£ÀÄß CªÀ®A©ü¹zÉ.
88. ZÁ¥Àgï «zÀÄå£ÀäAqÀ®ªÀÅ PÁ® C£ÀÄ¥ÁvÀ
¤AiÀÄAvÀæt vÀvÀézÀ ªÉÄÃ¯É gÀÆ¥ÀÄUÉÆArzÀÄÝ
2 kHz DªÀvÁðAPÀzÀ°è 220 V r.¹.
¥ÀÆgÉʸÀ¯ÁVzÉ. ¯ÉÆÃqï ªÉÇïÉÖÃeï 170 V
DzÁUÀ ªÀºÀ£À (Conduction) CªÀ¢üAiÀÄÄ
__________
(1) 0.5 ms
(2) 0.386 ms
(3) 0.114 ms
(4) 2 ms
89. ªÉÄÊPÉÆæÃ¥ÉÆæøɸÀgï r.JªÀiï.J. PÁAiÀiÁðZÀgÀuÉ PÉÊUÉƼÀî®Ä ¥Éj¥sÉgÀ¯ï ¸ÁzsÀ£ÀªÀÅ PÉÆÃjzÁUÀ F ¥ÉÊQ AiÀiÁªÀ ¸ÀAeÉÕAiÀÄ£ÀÄß §¼À¸À¯ÁUÀĪÀÅzÀÄ
(1) IO/��
(2) READY
(3) HOLD and HLDA
(4) 𝑅𝐷 𝑎𝑛𝑑 𝑊𝑅
222 (33 – A )
85) If the applied voltage of a certain
transformer is increased by 50% and the
frequency is reduced by 50% (assuming
that the magnetic circuit remains
unsaturated) the max core flux density
will
(1) Change to 3 times the original value
(2) Change to 1.5 times the original
value
(3) Change to 0.5 times the original
value
(4) Remain the same as the original
value
86) The logic circuit gives in the figure
represents
(1) Full adder
(2) Half adder
(3) Half subtractor
(4) Boolean multiplier
87) In a phase controlled bridge rectifier with
an increase of overlap angle, the output
DC voltage
(1) decreases
(2) increases
(3) does not change
(4) depends upon load inductance
88) A chopper circuit is operating on time
ratio control principal at a frequency of
2 kHz on a 220 V dc supply. If the load
voltage is 170 V the conduction period is
______
(1) 0.5 ms
(2) 0.386 ms
(3) 0.114 ms
(4) 2 ms
89) Which of the following signals is used
when a peripheral device request the
microprocessor to have a DMA operation ?
(1) IO/��
(2) READY
(3) HOLD and HLDA
(4) 𝑅𝐷 𝑎𝑛𝑑 𝑊𝑅
222 (34 – A )
90. 8051 add A, #77 £À ¸ÀÆZÀ£ÉAiÀÄÄ, ______ CqÉæ¹AUï.
(1) ¨ÁåAPï
(2) PÀÆqÀ¯ÉÃ
(3) £ÉÃgÀ ¸Àäøw
(4) ¥ÀgÉÆÃPÀë
91. J.¹.J¸ï.Dgï. ªÁºÀPÀªÀ£ÀÄß vÁªÀÄæzÀ §zÀ¯ÁV NªÀgï ºÉqï «zÀÄåvï ¯ÉÊ£ïUÀ¼À°è §¼ÀPÉ ªÀiÁqÀ®Ä PÁgÀt
(1) C¢üPÀªÁzÀ «zÀÄåvïªÀºÀ£À ¸ÁªÀÄxÀåð
(2) vÀÆPÀzÀ°è ºÀUÀÄgÀªÁzÀzÀÄÝ
(3) «ÄvÀªÀå¬ÄÃ
(4) PÀµÀðtzÀ C¢üPÀ GzÀÝ
92. «ÄAZÀÄ ¤§ðAzsÀPÀªÀ£ÀÄß «zÀÄåvï vÀAw ªÀÄvÀÄÛ ¨sÀÆ«ÄAiÀÄ £ÀqÀÄªÉ ¥ÀªÀgï ªÀåªÀ¸ÉÜAiÀÄ°è C¼ÀªÀr¹zÁUÀ
(1) l«Äð£À¯ï G¥ÀPÀgÀtUÀ¼À£ÀÄß ºÀjªÀ «zÀÄåvï¤AzÀ gÀQë¸ÀÄvÀÛzÉ
(2) l«Äð£À¯ï G¥ÀPÀgÀtUÀ¼À£ÀÄß £ÉÃgÀ «ÄAa£À WÁvÀ¢AzÀ gÀQë¸ÀÄvÀÛzÉ
(3) D ¸ÀªÀÄAiÀÄzÀ°è «zÀÄåvï ºÀjªÀ vÀAwAiÀÄ°è C¢üPÀ DAzÉÆîPÀUÀ¼À£ÀÄß ºÀwÛPÀÄÌvÀÛzÉ
(4) CzÀgÉqÉUÉ §gÀĪÀ ZÀ°¸ÀĪÀ C¯ÉUÀ¼À£ÀÄß »ªÉÄänÖ¸ÀÄvÀÛzÉ.
93. KPÀ«zÀÄåvï vÀAw ªÀÄvÀÄÛ UËæAqï zÉÆõÀ PÀAqÀÄ §AzÀ°è zÉÆõÀ ¥ÁæªÀ¸ÉÜAiÀÄ°è «zÀÄåvï 100 A ±ÀÆ£Àå C£ÀÄPÀæªÀÄ «zÀÄåvï
(1) ±ÀÆ£Àå
(2) 33.3 A
(3) 66.6 A
(4) 100 A
94. «zÀÄåvï ¥ÀjªÀvÀðPÀzÀ ²µÀÖ (¸ÁÖöåAqÀqïð) EA¥À¯ïì ¥ÀjÃPÉëUÉ EzÀÄ ¨ÉÃPÀÄ
(1) ZÁ¥ïØ vÀgÀAUÀzÀ JgÀqÀÄ C£ÀéAiÀÄUÀ¼ÀÄ ªÀÄvÀÄÛ CzÀ£ÀߣÀĸÀj¸ÀĪÀ ¥ÀÆtð C¯ÉAiÀÄ MAzÀÄ C£ÀéAiÀÄ
(2) ZÁ¥ïØ vÀgÀAUÀzÀ MAzÀÄ C£ÀéAiÀÄ ªÀÄvÀÄÛ CzÀ£ÀߣÀĸÀj¸ÀĪÀ ¥ÀÆtð C¯ÉAiÀÄ MAzÀÄ C£ÀéAiÀÄ
(3) ZÁ¥ïØ vÀgÀAUÀzÀ MAzÀÄ C£ÀéAiÀÄ ªÀÄvÀÄÛ CzÀ£ÀߣÀĸÀj¸ÀĪÀ ¥ÀÆtð C¯ÉAiÀÄ JgÀqÀÄ C£ÀéAiÀÄUÀ¼ÀÄ
(4) F AiÀiÁªÀŪÀÇ C®è
95. ak ¨Ü Z ±ÜÄÊÜñÜìPÜÊÜâ
(1) a–Z
Z
(2) 1–Z
Z
(3) 1
(4)
222 (35 – A )
90) The instruction of 8051 add A, #77 is
_____ addressing.
(1) Bank
(2) Immediate
(3) Direct memory
(4) Indirect
91) ACSR conductor is used in place of copper
in overhead power lines because of
(1) Higher current carrying capacity
(2) Being lighter in weight
(3) Economy
(4) Higher tensile length
92) A lightning arrestor connected between
the line and the earth in a power system
(1) Protects the terminal equipment
against travelling surges
(2) Protects the terminal equipment
against direct lightning stroke
(3) Suppresses high frequency
oscillations in the time
(4) Reflects back the travelling waves
approaching it
93) When a single line to ground fault occurs
the current in the faulted phase is 100 A.
the zero sequence current is
(1) Zero
(2) 33.3 A
(3) 66.6 A
(4) 100 A
94) Standard impulse testing of a power
transformer requires
(1) Two applications of chopped wave
followed by one application of full
wave
(2) One applications of chopped wave
followed by one application of full
wave
(3) One application of chopped wave
followed by two application of full
wave
(4) None of these
95) The Z transform of ak is
(1) a–Z
Z
(2) 1–Z
Z
(3) 1
(4)
222 (36 – A )
96. ªÉÇïÉÖÃeï ¤AiÀÄAwævÀ §¸ï C£ÀÄß ¯ÉÆÃqï §¸ï JAzÀÄ C£ÀAvÀgÀzÀ°è ElgÉõÀ£ï ªÀiÁqÀĪÀÅzÀÄ AiÀiÁªÁUÀ JAzÀgÉ
(1) ªÉÇïÉÖÃeï «ÄwAiÀÄ£ÀÄß «ÄÃgÀĪÁUÀ
(2) ¸ÀQæAiÀÄ «zÀÄåvï ¸ÁªÀÄxÀåð «Äw «ÄÃgÀĪÁUÀ
(3) QæAiÀiÁ²Ã® «zÀÄåvï ¸ÁªÀÄxÀåð «Äw «ÄÃgÀĪÁUÀ
(4) ¥ÁæªÀ¸ÁÜ PÉÆãÀ«Äw «ÄÃgÀĪÁUÀ
97. «ÄvÀªÀåAiÀÄPÀgÀ PÁAiÀiÁðZÀgÀuÉUÉ CvÀå¢üPÀ zsÀ£ÁvÀäPÀ ºÉZÀÄѪÀj ¥Àæ¸ÀgÀt £ÀµÀÖªÀÅ »ÃUÉ ¤ªÀðºÀuÉAiÀiÁUÀÄvÀÛzÉ.
(1) PÀ¤µÀ× zsÀ£ÁvÀäPÀ GvÁàzÀ£Á ªÉZÀÑ
(2) PÀ¤µÀ× IÄuÁvÀäPÀ ºÉZÀѪÀj GvÁàzÀ£Á ªÉZÀÑ
(3) CvÀå¢üPÀ zsÀ£ÁvÀäPÀ ºÉZÀÄѪÀj GvÁàzÀ£Á ªÉZÀÑ
(4) F ªÉÄð£À AiÀiÁªÀŪÀÇ C®è
98. ¯ÉÆÃqï DªÀvÁðAPÀ ¤AiÀÄAvÀætªÀ£ÀÄß ¥ÀævÉåÃPÀ ªÉĶ£ïUÀ¼À ¸ÀjAiÀiÁzÀ ºÉÆAzÁtÂPɬÄAzÀ ¸Á¢ü¸À¯ÁUÀĪÀÅzÀÄ
(1) QæAiÀiÁvÀäPÀ «zÀÄåvï ¸ÁªÀÄxÀåð
(2) GvÁࢹzÀ ªÉÇïÉÖÃeï
(3) l¨ÉÊð£ÀÄ DUÀvÀ
(4) l¨ÉÊð£ÀÄ ªÀÄvÀÄÛ GvÁàzÀPÀ zÀgÀ ¤zsÁðgÀ
99. ¥Àæ±À¸ÀÛ GvÁàzÀPÀ µÉqÀÆå°AUïC£ÀÄß ««zsÀ «zÀÄåvï ¸ÁܪÀgÀUÀ¼À°è ªÀiÁqÀĪÁUÀ ªÀÄÄRå EAzsÀ£À ªÉZÀѪÀ£ÀÄß ¥ÀqÉAiÀÄĪÀÅzÀÄ »ÃVzÁÝUÀ
(1) ºÉZÀÄѪÀj EAzsÀ£À ªÉZÀѪÀÅ ¥Àæw ¸ÁܪÀgÀPÀÆÌ
MAzÉà EgÀ¨ÉÃPÀÄ
(2) ¥Àæw ¸ÁܪÀgÀPÀÆÌ ¥É£Á°Ö CA±À CµÉÖÃ
EgÀ¨ÉÃPÀÄ
(3) ¥Àæw ¸ÁܪÀgÀPÀÆÌ ºÉZÀÄѪÀj EAzsÀ£À ªÉZÀÑ
ºÁUÀÆ ¥É£Á°Ö CA±ÀzÀ C£ÀÄ¥ÁvÀ CzÉÃ
EgÀ¨ÉÃPÀÄ
(4) ¥Àæw ¸ÁܪÀgÀPÀÆÌ ºÉZÀÄѪÀj EAzsÀ£ÀªÉZÀÑ
ªÀÄvÀÄÛ ¥É£Á°Ö CA±ÀzÀ UÀÄt®§ÞªÀÅ CzÉà EgÀ¨ÉÃPÀÄ
100. PÁAiÀÄð ¸ÀªÀÄvÀ®zÀ PÀ¤µÀתÀ£ÀÄß vÀ®Ä¥ÀĪÀ
®Æ«Ä£À¸ï ºÁ¼É EzÀ£ÀߪÀ®A©¹zÉ.
(1) PÉÆoÀrAiÀÄ DAiÀiÁªÀÄ
(2) ¢Ã¥ÀzÀ ®ÄªÉÄ£ï ¤UÀðvÀ ¨É¼ÀPÀÄ
(3) PÁAiÀÄð ¸ÀªÀÄvÀ® ªÉÄïÉäöÊAiÀÄ §tÚ
(4) DAvÀjPÀ ªÉÄïÉäöÊ ¥Àæw¥sÀ®£À
222 (37 – A )
96) A voltage controlled bus is treated as a
load bus in subsequent iteration when
(1) Voltage limit is violated
(2) Active power limit is violated
(3) Reactive power limit is violated
(4) Phase angle limit is violated
97) For economic operation the generator
with highest positive incremental
transmission loss will operate at
(1) The lowest positive cost of
production
(2) The lowest negative incremental
cost of production
(3) The highest positive incremental
cost of production
(4) None of the above
98) Load frequency control is achived by
properly matching the individual
machines
(1) Reactive powers
(2) Generated voltage
(3) Turbine input
(4) Turbine and generator rating
99) In the optimum generator scheduling of
different power plants, the main fuel cost
is obtained when
(1) Only the incremental fuel cost of
each plant is same
(2) The penalty factor of each plant is
same
(3) The ratio of the incremental fuel
cost to the penalty factor of each
plant is same
(4) The incremental fuel cost of each
plant multiplied by its penalty factor
is the same
100) The luminous sheet reaching the working
plane least depends on
(1) Dimension of the room
(2) The lumen output of the lamp
(3) Colour of the working plane surface
(4) Reflection of internal surface
222 (38 – A )
SPACE FOR ROUGH WORK
222 (39 – A )
SPACE FOR ROUGH WORK
222 (40 – A )
DO NOT OPEN THIS QUESTION BOOKLET UNTIL YOU ARE ASKED TO DO SO
Question Booklet Series
QUESTION BOOKLET
SPECIFIC PAPER
(PAPER II)
Time Allowed : 2 Hours Maximum Marks : 200
INSTRUCTIONS
1. Immediately after the commencement of the Examination, before writing the Question Booklet Series
in the OMR sheet, you should check that this Question Booklet does NOT have any unprinted or torn
or missing pages or questions etc. If so, get it replaced by a complete ‘Question Booklet’ of the
available series.
2. Write and encode clearly the Question Booklet Series A, B, C or D, Subject Code and
Register Number in the appropriate space provided for that purpose in the OMR Answer
Sheet. Also ensure that candidate’s signature and Invigilator’s signature columns are
properly filled in. Please note that it is candidate’s responsibility to fill in and encode
these particulars and any omission/discrepancy will render the OMR Answer Sheet liable
for Rejection.
3. You have to enter your Register Number in the
Question Booklet in the box provided alongside.
DO NOT write anything else on the Question Booklet.
4. This Question Booklet contains 100 questions. Each question contains four responses (answers).
Select the response which you want to mark on the Answer Sheet. In case you feel that there is more
than one correct response, mark the response which you consider the most appropriate. In any case,
choose ONLY ONE RESPONSE for each question.
5. All the responses should be marked ONLY on the separate Answer Sheet provided and ONLY in
Black or Blue Ball Point Pen. See detailed instructions in the OMR Answer Sheet.
6. All questions carry equal marks. Attempt all questions. Every question for which wrong answer has been given by the candidate, 1/4th (0.25) of the marks assigned for that question will be deducted.
7. Sheets for rough work are appended in the Question Booklet at the end. You should not make any
marking on any other part of the Question Booklet.
8. Immediately after the final bell indicating the conclusion of the examination, stop making any further
markings in the Answer Sheet. Be seated till the Answer Sheets are collected and accounted for by
the Invigilator.
9. Questions are printed both in Kannada and English. If any confusion arises in the
Kannada Version, please refer to the English Version of the questions. Please note that in
case of any confusion the English Version of the Question Booklet is final.
WÜÊÜá¯Ô : ÓÜãaÜ®æWÜÙÜ PܮܰvÜ BÊÜ꣤¿áá D ±ÜÅÍæ° ±ÜâÔ¤Pæ¿á ÊÜááí»ÝWÜ ÜÈÉ ÊÜáá©ÅÓÜƳqr æ.
A SUBJECT CODE : 222
Register Number
Use of Mobile Phones, Calculators and other Electronic/Communication gadgets of any kind
is prohibited inside the Examination venue.