McqMate
These multiple-choice questions (MCQs) are designed to enhance your knowledge and understanding in the following areas: Computer Science Engineering (CSE) , Information Technology Engineering (IT) , Bachelor of Science in Computer Science SY (BSc CS) , Bachelor of Computer Applications (BCA) , Bachelor of Business Administration in Computer Applications (BBA [CA]) .
Chapters
| 351. |
If all the application processing and data management is carried out on the server and client is only responsible for running the system then this is referred as |
| A. | Client-server model |
| B. | Thin client server model |
| C. | Thick client server model |
| D. | None of these |
| Answer» B. Thin client server model | |
| 352. |
If the server is only responsible for data management and software on the client implements the application logic, then one can referrer this model as |
| A. | Client server model |
| B. | Fat client server model |
| C. | Thin client server model |
| D. | None of these |
| Answer» B. Fat client server model | |
| 353. |
In system models, object is |
| A. | An entity that has a state and defined set of operations that operates on that state |
| B. | Software program |
| C. | Programming language, that develops any given program |
| D. | None of these |
| Answer» A. An entity that has a state and defined set of operations that operates on that state | |
| 354. |
When the state of object changes by internal operations, executing within the object it self, then these objects are referred as |
| A. | Active object |
| B. | Inactive object |
| C. | Silent object |
| D. | None of these |
| Answer» A. Active object | |
| 355. |
The objects that are realized on call as parallel process with method corresponding to defined object operations can be referred as |
| A. | Active object |
| B. | Servers |
| C. | Modules |
| D. | None of these |
| Answer» B. Servers | |
| 356. |
For real time system following is not true |
| A. | Correct functioning of the system depends on the result produced by the system |
| B. | Correct functioning of the system depends on the time at which the results are produced |
| C. | The time of processing affects the system output |
| D. | The time of processing does not affects the system out-put |
| Answer» D. The time of processing does not affects the system out-put | |
| 357. |
If in a software system, the operation is degraded if results are not produced according to the specified timing require- ments then the software system is referred as |
| A. | Soft real time system |
| B. | hard real time system |
| C. | Real time system |
| D. | None of these |
| Answer» A. Soft real time system | |
| 358. |
If in a software system, the operation is incorrect if results are not produced accor- ding to the specified timing requirements then the software system is referred as |
| A. | Soft real time system |
| B. | Hard real time system |
| C. | Real time system |
| D. | None of these |
| Answer» A. Soft real time system | |
| 359. |
Degree to which a system or component performs only the necessary functions relevant to a particular purpose |
| A. | Abstractness |
| B. | Acceptable risk |
| C. | Acceptance testing |
| D. | None of these |
| Answer» A. Abstractness | |
| 360. |
Subject to probability of hazard, arising will not raise cost factors is referred as |
| A. | Abstractness |
| B. | Acceptable risk |
| C. | Acceptance testing |
| D. | None of these |
| Answer» B. Acceptable risk | |
| 361. |
Formal testing conducted to determine whether a system satisfies its acceptance criteria and to enable the customer to determine whether to accept the system |
| A. | Abstractness |
| B. | Acceptable risk |
| C. | Acceptance testing |
| D. | None of these |
| Answer» C. Acceptance testing | |
| 362. |
Truthfulness with which software satisfies differing system constraints and user needs is |
| A. | Active objects |
| B. | Activity |
| C. | Adaptability |
| D. | None of these |
| Answer» C. Adaptability | |
| 363. |
Adaptive measures are |
| A. | Quality measures that address how easily a system can evolve or migrate |
| B. | Piece of software that acts to accomplish tasks on behalf of its user |
| C. | A quantitative option analysis that allows the cost of various options to be compu- ted, and options can be compared on objective basis |
| D. | Extent to which a software system or component allows for or supports anonymous transactions |
| Answer» A. Quality measures that address how easily a system can evolve or migrate | |
| 364. |
An Acquisition cycle time is |
| A. | Unplanned events, which results in injury, damage to property, or to the environment |
| B. | Quantitative measure of the magnitude of error |
| C. | Period that starts when a system is considered and ends when the product meets its initial operational capability |
| D. | All the above |
| Answer» C. Period that starts when a system is considered and ends when the product meets its initial operational capability | |
| 365. |
An accuracy is |
| A. | Unplanned events, which results in injury, damage to property, or to the environment |
| B. | Quantitative measure of the magnitude of error |
| C. | Period that starts when a system is considered and ends when the product meets its initial operational capability |
| D. | All the above |
| Answer» B. Quantitative measure of the magnitude of error | |
| 366. |
Here the state of the object changes by internal operations executing within the object itself. And also object continually executes and operations never suspend itself is referred as |
| A. | Active objects |
| B. | Activity |
| C. | Adaptability |
| D. | None of these |
| Answer» A. Active objects | |
| 367. |
A clearly defined objective, entry and exit conditions which is normally is atomic is referred as |
| A. | Active objects |
| B. | Activity |
| C. | Adaptability |
| D. | None of these |
| Answer» B. Activity | |
| 368. |
Agents are |
| A. | Quality measures that address how easily a system can evolve or migrate |
| B. | Piece of software that acts to accomplish tasks on behalf of its user |
| C. | A quantitative option analysis that allows the cost of various options to be compu- ted, and options can be compared on objective basis |
| D. | Extent to which a software system or component allows for or supports anonymous transactions |
| Answer» B. Piece of software that acts to accomplish tasks on behalf of its user | |
| 369. |
Algorithmic cost modeling is |
| A. | Quality measures that address how easily a system can evolve or migrate |
| B. | Piece of software that acts to accomplish tasks on behalf of its user |
| C. | A quantitative option analysis that allows the cost of various options to be computed, and options can be compared on objective basis |
| D. | Extent to which a software system or component allows for or supports anonymous transactions |
| Answer» A. Quality measures that address how easily a system can evolve or migrate | |
| 370. |
Method of defining a collection of hardware and software components and their interfaces to establish the framework for the development of a computer system |
| A. | As low as reasonably practical (ALARP) risk |
| B. | Architectural design |
| C. | Attack |
| D. | None of these |
| Answer» B. Architectural design | |
| 371. |
Probability of an accident arising because of hazard is minimum subject of other costs |
| A. | As low as reasonably practical (ALARP) risk |
| B. | Architectural design |
| C. | Attack |
| D. | None of these |
| Answer» A. As low as reasonably practical (ALARP) risk | |
| 372. |
Fault tolerance system are |
| A. | These system runs on a single proce- ssor or an integrated group of processors |
| B. | A system where each sub-system can respond to generated events where the events might be generated from other sub-systems or from the environment of the system. |
| C. | A system continues in operation after some system faults have manifested themselves. |
| D. | A system whose operation is incorrect, if results are not produced according to the timing specifications |
| Answer» C. A system continues in operation after some system faults have manifested themselves. | |
| 373. |
The misuse of system vulnerability is |
| A. | As low as reasonably practical (ALARP) risk |
| B. | Architectural design |
| C. | Attack |
| D. | None of these |
| Answer» C. Attack | |
| 374. |
Attribute-based identification is |
| A. | Here each component has a unique name and an associated set of attribute, which differs for each version of component |
| B. | Extent to which a software system records information concerning transactions performed against the system. |
| C. | Extent to which a system or component is operational and accessible when required for use |
| D. | They are used to describe the over all behavior of the system. Auditable is |
| Answer» A. Here each component has a unique name and an associated set of attribute, which differs for each version of component | |
| 375. |
Availability is |
| A. | Here each component has a unique name and an associated set of attribute, which differs for each version of component |
| B. | Extent to which a software system records information concerning transac- tions performed against the system. |
| C. | Extent to which a system or component is operational and accessible when required for use |
| D. | They are used to describe the over all behavior of the system. |
| Answer» C. Extent to which a system or component is operational and accessible when required for use | |
| 376. |
Behavioral models is |
| A. | Here each component has a unique name and an associated set of attribute, which differs for each version of component |
| B. | Extent to which a software system records information concerning transac- tions performed against the system. |
| C. | Extent to which a system or component is operational and accessible when required for use |
| D. | Used to describe the over all behavior of the system |
| Answer» D. Used to describe the over all behavior of the system | |
| 377. |
In Bottom-up integration |
| A. | The low-level components of a system are integrated and tested before the higher-level components have been developed |
| B. | The testing process starts with modules at lower levels in the hierarchy and works up the hierarchy of modules until the final module is tested. |
| C. | An event driven control system, where an event is broadcasted to each sub- system and any sub-system that can handle that event responds to it. |
| D. | Control starts of the top of a sub routine hierarchy and through sub routine calls passes to lower levels. |
| Answer» A. The low-level components of a system are integrated and tested before the higher-level components have been developed | |
| 378. |
In Broadcast models |
| A. | The low-level components of a system are integrated and tested before the higher-level components have been developed. |
| B. | The testing process starts with modules at lower levels in the hierarchy and works up the hierarchy of modules until the final module is tested |
| C. | An event driven control system, where an event is broadcasted to each sub- system and any sub-system that can handle that event responds to it. |
| D. | Control starts of the top of a sub routine hierarchy and through sub routine calls passes to lower levels. |
| Answer» C. An event driven control system, where an event is broadcasted to each sub- system and any sub-system that can handle that event responds to it. | |
| 379. |
Bottom-up testing |
| A. | The low-level components of a system are integrated and tested before the higher-level components have been developed. |
| B. | The testing process starts with modules at lower levels in the hierarchy and works up the hierarchy of modules until the final module is tested. |
| C. | An event driven control system, where an event is broadcasted to each sub- system and any sub-system that can handle that event responds to it. |
| D. | Control starts of the top of a sub routine hierarchy and through sub routine calls passes to lower levels. |
| Answer» B. The testing process starts with modules at lower levels in the hierarchy and works up the hierarchy of modules until the final module is tested. | |
| 380. |
In Call-return control model |
| A. | The low-level components of a system are integrated and tested before the higher-level components have been developed. |
| B. | The testing process starts with modules at lower levels in the hierarchy and works up the hierarchy of modules until the final module is tested. |
| C. | An event driven control system, where an event is broadcasted to each sub- system and any sub-system that can handle that event responds to it. |
| D. | Control starts of the top of a sub routine hierarchy and through sub routine calls passes to lower levels |
| Answer» D. Control starts of the top of a sub routine hierarchy and through sub routine calls passes to lower levels | |
| 381. |
Capacity is |
| A. | A measure of the amount of work a system can perform |
| B. | It provides automated support for software process. |
| C. | Support individual process tasks |
| D. | Set of tools to support a particular phase of software process such as design, implementation or testing. |
| Answer» A. A measure of the amount of work a system can perform | |
| 382. |
CASE (Computer Aided Software Engineering) is |
| A. | A measure of the amount of work a system can perform |
| B. | It provides automated support for software process. |
| C. | Support individual process tasks |
| D. | Set of tools to support a particular phase of software process such as design, implementation or testing: |
| Answer» B. It provides automated support for software process. | |
| 383. |
CASE Tools |
| A. | A measure of the amount of work a system can perform |
| B. | It provides automated support for software process. |
| C. | Support individual process tasks |
| D. | Set of tools to support a particular phase of software process such as design, implementation or testing |
| Answer» C. Support individual process tasks | |
| 384. |
CASE Workbench |
| A. | A measure of the amount of work a system can perform |
| B. | It provides automated support for software process. |
| C. | Support individual process tasks |
| D. | Set of tools to support a particular phase of software process such as design, implementation or testing |
| Answer» A. A measure of the amount of work a system can perform | |
| 385. |
Centralized control models |
| A. | Here one system is designed as the system controller and has responsibility for managing the execution of other subsystems. |
| B. | Each system is named as in attribute- based identification and associated with one or more change requests. |
| C. | An object class inheritance diagram, how entities have common characteristics. |
| D. | The objective of this software development is zero-defect software. |
| Answer» A. Here one system is designed as the system controller and has responsibility for managing the execution of other subsystems. | |
| 386. |
Change-oriented identification |
| A. | One system is designed as the system controller and has responsibility for managing the execution of other subsystems. |
| B. | Each system is named as in attribute- based identification and associated with one or more change requests. |
| C. | An object class inheritance diagram, how entities have common characteristics. |
| D. | The objective of this software development is zero-defect software. |
| Answer» B. Each system is named as in attribute- based identification and associated with one or more change requests. | |
| 387. |
Hard real time systems are |
| A. | These system runs on a single processor or an integrated group of processors |
| B. | A system where each sub-system can respond to generated events where the events might be generated from other sub-systems or from the environment of the system. |
| C. | A system continues in operation after some system faults have manifested themselves. |
| D. | A system whose operation is incorrect, if results are not produced according to the timing specifications |
| Answer» D. A system whose operation is incorrect, if results are not produced according to the timing specifications | |
| 388. |
Classification model |
| A. | One system is designed as the system controller and has responsibility for managing the execution of other subsystems. |
| B. | Each system is named as in attribute- based identification and associated with one or more change requests. |
| C. | An object class inheritance diagram, how entities have common characteristics. |
| D. | The objective of this software develop- ment is zero-defect software. |
| Answer» C. An object class inheritance diagram, how entities have common characteristics. | |
| 389. |
Clean room software development |
| A. | One system is designed as the system controller and has responsibility for managing the execution of other subsystems. |
| B. | Each system is named as in attribute- based identification and associated with one or more change requests. |
| C. | An object class inheritance diagram, how entities have common characteristics. |
| D. | The objective is to develop zero-defect software. |
| Answer» D. The objective is to develop zero-defect software. | |
| 390. |
COCOMO cost model |
| A. | It takes project, product hardware and personnel attributes into account when formulating a cost estimate. |
| B. | In it server provides set of services and set of clients uses these services. |
| C. | Extent to which standards are used to achieve interoperability. |
| D. | None of these |
| Answer» A. It takes project, product hardware and personnel attributes into account when formulating a cost estimate. | |
| 391. |
Client server architecture |
| A. | It takes project, product hardware and personnel attributes into account when formulating a cost estimate. |
| B. | In it server provides set of services and set of clients uses these services. |
| C. | Extent to which standards are used to achieve interoperability. |
| D. | None of these |
| Answer» B. In it server provides set of services and set of clients uses these services. | |
| 392. |
Commonality |
| A. | It takes project, product hardware and personnel attributes into account when formulating a cost estimate. |
| B. | In it server provides set of services and set of clients uses these services. |
| C. | Extent to which standards are used to achieve interoperability |
| D. | None of these |
| Answer» C. Extent to which standards are used to achieve interoperability | |
| 393. |
Transforming of logic and data from design specifications (design descriptions) into a programming language |
| A. | Compatibility |
| B. | Compactness |
| C. | Coding |
| D. | Communication |
| Answer» C. Coding | |
| 394. |
An inter change of information between computer systems and peoples or between people. |
| A. | Compatibility |
| B. | Compactness |
| C. | Coding |
| D. | Communication |
| Answer» D. Communication | |
| 395. |
Extent to which a system or component makes efficient use of its data storage space- occupies a small volume. |
| A. | Compatibility |
| B. | Compactness |
| C. | Code |
| D. | Communication |
| Answer» B. Compactness | |
| 396. |
Entity-relation model is |
| A. | It describes the basic entities in the design and relation between them. |
| B. | Observational techniques used to understand social and organizational requirements. |
| C. | It is based on the idea of developing an initial implementation, exposing it uses on requirement and refining it through many versions until an adequate system has been developed. |
| D. | Based on an idea of developing an initial implementation, exposing this to uses comment and retiring it until and adequate system has been developed. |
| Answer» A. It describes the basic entities in the design and relation between them. | |
| 397. |
Ability of two or more systems or components to perform their required functions while sharing the same hardware or software environment |
| A. | Compatibility |
| B. | Compactness |
| C. | Code |
| D. | Communication |
| Answer» A. Compatibility | |
| 398. |
Completeness in software system is referred as |
| A. | Extent to which all the parts of a software system or component are present and each of its parts is fully specified and developed. |
| B. | Testing of individual hardware/software components |
| C. | An Entity-relation (E-R) diagram show how entities in the system are composed of other entities. |
| D. | It consists of wide range of different types of computer programs, which be used to support software process activities such as a requirement analysis, system modeling, debugging and testing. |
| Answer» A. Extent to which all the parts of a software system or component are present and each of its parts is fully specified and developed. | |
| 399. |
Composition model is |
| A. | Extent to which all the parts of a software system or component are present and each of its parts is fully specified and developed. |
| B. | Testing of individual hardware/software components |
| C. | An Entity-relation (E-R) diagram show how entities in the system are composed of other entities |
| D. | It consists of wide range of different types of computer programs, which be used to support software process activities such as a requirement analysis, system modeling, debugging and testing. |
| Answer» C. An Entity-relation (E-R) diagram show how entities in the system are composed of other entities | |
| 400. |
Match the following :
|
| A. | A-1, B-2,C-3,D-4 |
| B. | A-4,B-3,C-2,D-1 |
| C. | A-3, B-2,C-1,D-4 |
| D. | None is true |
| Answer» A. A-1, B-2,C-3,D-4 | |
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