200-201 Understanding Cisco Cybersecurity Operations Fundamentals (CBROPS) Exam Dumps Free Downloads

200-201 Understanding Cisco Cybersecurity Operations Fundamentals (CBROPS) Exam
Duration: 120 minutes
Languages: English
Associated certification : Cisco Certified CyberOps Associate

Exam overview
This exam tests your knowledge and skills related to:
Security concepts
Security monitoring
Host-based analysis
Network intrusion analysis
Security policies and procedures

Exam preparation
Official Cisco training

Understanding Cisco Cybersecurity Operations Fundamentals (CBROPS)
CBROPS training videos
CBROPS study materials
Understanding Cisco Cybersecurity Operations Fundamentals v1.0 (200-201)

Exam Description:
The Understanding Cisco Cybersecurity Operations Fundamentals (CBROPS) exam (200-201) is a 120-minute assessment that is associated with the Cisco Certified CyberOps Associate certification. The CBROPS exam tests a candidate’s knowledge and skills related to security concepts, security monitoring, host-based analysis, network intrusion analysis, and security policies and procedures. The course, Understanding Cisco Cybersecurity Operations Fundamentals, helps candidates to prepare for this exam.

The following topics are general guidelines for the content likely to be included on the exam. However, other related topics may also appear on any specific delivery of the exam. To better reflect the contents of the exam and for clarity purposes, the guidelines below may change at any time without notice.

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20% 1.0 Security Concepts
1.1 Describe the CIA triad
1.2 Compare security deployments
1.2.a Network, endpoint, and application security systems
1.2.b Agentless and agent-based protections
1.2.c Legacy antivirus and antimalware
1.2.d SIEM, SOAR, and log management
1.3 Describe security terms
1.3.a Threat intelligence (TI)
1.3.b Threat hunting
1.3.c Malware analysis
1.3.d Threat actor
1.3.e Run book automation (RBA)
1.3.f Reverse engineering
1.3.g Sliding window anomaly detection
1.3.h Principle of least privilege
1.3.i Zero trust
1.3.j Threat intelligence platform (TIP)
1.4 Compare security concepts
1.4.a Risk (risk scoring/risk weighting, risk reduction, risk assessment)
1.4.b Threat
1.4.c Vulnerability
1.4.d Exploit
1.5 Describe the principles of the defense-in-depth strategy
1.6 Compare access control models
1.6.a Discretionary access control
1.6.b Mandatory access control
1.6.c Nondiscretionary access control
1.6.d Authentication, authorization, accounting
1.6.e Rule-based access control
1.6.f Time-based access control
1.6.g Role-based access control
1.7 Describe terms as defined in CVSS
1.7.a Attack vector
1.7.b Attack complexity
1.7.c Privileges required
1.7.d User interaction
1.7.e Scope
1.8 Identify the challenges of data visibility (network, host, and cloud) in detection
1.9 Identify potential data loss from provided traffic profiles
1.10 Interpret the 5-tuple approach to isolate a compromised host in a grouped set of logs
1.11 Compare rule-based detection vs. behavioral and statistical detection

25% 2.0 Security Monitoring

2.1 Compare attack surface and vulnerability
2.2 Identify the types of data provided by these technologies
2.2.a TCP dump
2.2.b NetFlow
2.2.c Next-gen firewall
2.2.d Traditional stateful firewall
2.2.e Application visibility and control
2.2.f Web content filtering
2.2.g Email content filtering
2.3 Describe the impact of these technologies on data visibility
2.3.a Access control list
2.3.b NAT/PAT
2.3.c Tunneling
2.3.d TOR
2.3.e Encryption
2.3.f P2P
2.3.g Encapsulation
2.3.h Load balancing
2.4 Describe the uses of these data types in security monitoring
2.4.a Full packet capture
2.4.b Session data
2.4.c Transaction data
2.4.d Statistical data
2.4.e Metadata
2.4.f Alert data
2.5 Describe network attacks, such as protocol-based, denial of service, distributed denial of service, and man-in-the-middle
2.6 Describe web application attacks, such as SQL injection, command injections, and crosssite scripting
2.7 Describe social engineering attacks
2.8 Describe endpoint-based attacks, such as buffer overflows, command and control (C2), malware, and ransomware
2.9 Describe evasion and obfuscation techniques, such as tunneling, encryption, and proxies
2.10 Describe the impact of certificates on security (includes PKI, public/private crossing the network, asymmetric/symmetric)
2.11 Identify the certificate components in a given scenario
2.11.a Cipher-suite
2.11.b X.509 certificates
2.11.c Key exchange
2.11.d Protocol version
2.11.e PKCS

20% 3.0 Host-Based Analysis
3.1 Describe the functionality of these endpoint technologies in regard to security monitoring
3.1.a Host-based intrusion detection
3.1.b Antimalware and antivirus
3.1.c Host-based firewall
3.1.d Application-level allow listing/block listing
3.1.e Systems-based sandboxing (such as Chrome, Java, Adobe Reader)
3.2 Identify components of an operating system (such as Windows and Linux) in a given scenario
3.3 Describe the role of attribution in an investigation
3.3.a Assets
3.3.b Threat actor
3.3.c Indicators of compromise
3.3.d Indicators of attack
3.3.e Chain of custody
3.4 Identify type of evidence used based on provided logs
3.4.a Best evidence
3.4.b Corroborative evidence
3.4.c Indirect evidence
3.5 Compare tampered and untampered disk image
3.6 Interpret operating system, application, or command line logs to identify an event
3.7 Interpret the output report of a malware analysis tool (such as a detonation chamber or sandbox)
3.7.a Hashes
3.7.b URLs
3.7.c Systems, events, and networking

20% 4.0 Network Intrusion Analysis
4.1 Map the provided events to source technologies
4.1.a IDS/IPS
4.1.b Firewall
4.1.c Network application control
4.1.d Proxy logs
4.1.e Antivirus
4.1.f Transaction data (NetFlow)
4.2 Compare impact and no impact for these items
4.2.a False positive
4.2.b False negative
4.2.c True positive
4.2.d True negative
4.2.e Benign
4.3 Compare deep packet inspection with packet filtering and stateful firewall operation
4.4 Compare inline traffic interrogation and taps or traffic monitoring
4.5 Compare the characteristics of data obtained from taps or traffic monitoring and transactional data (NetFlow) in the analysis of network traffic
4.6 Extract files from a TCP stream when given a PCAP file and Wireshark
4.7 Identify key elements in an intrusion from a given PCAP file
4.7.a Source address
4.7.b Destination address
4.7.c Source port
4.7.d Destination port
4.7.e Protocols
4.7.f Payloads
4.8 Interpret the fields in protocol headers as related to intrusion analysis
4.8.a Ethernet frame
4.8.b IPv4
4.8.c IPv6
4.8.d TCP
4.8.e UDP
4.8.f ICMP
4.8.g DNS
4.8.h SMTP/POP3/IMAP
4.8.i HTTP/HTTPS/HTTP2
4.8.j ARP
4.9 Interpret common artifact elements from an event to identify an alert
4.9.a IP address (source / destination)
4.9.b Client and server port identity
4.9.c Process (file or registry)
4.9.d System (API calls)
4.9.e Hashes
4.9.f URI / URL
4.10 Interpret basic regular expressions

15% 5.0 Security Policies and Procedures

5.1 Describe management concepts
5.1.a Asset management
5.1.b Configuration management
5.1.c Mobile device management
5.1.d Patch management
5.1.e Vulnerability management
5.2 Describe the elements in an incident response plan as stated in NIST.SP800-61
5.3 Apply the incident handling process (such as NIST.SP800-61) to an event
5.4 Map elements to these steps of analysis based on the NIST.SP800-61
5.4.a Preparation
5.4.b Detection and analysis
5.4.c Containment, eradication, and recovery
5.4.d Post-incident analysis (lessons learned)
5.5 Map the organization stakeholders against the NIST IR categories (CMMC, NIST.SP800-61)
5.5.a Preparation
5.5.b Detection and analysis
5.5.c Containment, eradication, and recovery
5.5.d Post-incident analysis (lessons learned)
5.6 Describe concepts as documented in NIST.SP800-86
5.6.a Evidence collection order
5.6.b Data integrity
5.6.c Data preservation
5.6.d Volatile data collection
5.7 Identify these elements used for network profiling
5.7.a Total throughput
5.7.b Session duration
5.7.c Ports used
5.7.d Critical asset address space
5.8 Identify these elements used for server profiling
5.8.a Listening ports
5.8.b Logged in users/service accounts
5.8.c Running processes
5.8.d Running tasks
5.8.e Applications
5.9 Identify protected data in a network
5.9.a PII
5.9.b PSI
5.9.c PHI
5.9.d Intellectual property
5.10 Classify intrusion events into categories as defined by security models, such as Cyber Kill Chain Model and Diamond Model of Intrusion
5.11 Describe the relationship of SOC metrics to scope analysis (time to detect, time to contain, time to respond, time to control)

QUESTION 1
Which event is user interaction?

A. gaining root access
B. executing remote code
C. reading and writing file permission
D. opening a malicious file

Correct Answer: D

QUESTION 2
Which security principle requires more than one person is required to perform a critical task?

A. least privilege
B. need to know
C. separation of duties
D. due diligence

Correct Answer: C

QUESTION 3
How is attacking a vulnerability categorized?

A. action on objectives
B. delivery
C. exploitation
D. installation

Correct Answer: C

QUESTION 4
What is a benefit of agent-based protection when compared to agentless protection?

A. It lowers maintenance costs
B. It provides a centralized platform
C. It collects and detects all traffic locally
D. It manages numerous devices simultaneously

Correct Answer: B

Section: Security Concepts

QUESTION 5
Which principle is being followed when an analyst gathers information relevant to a security incident to determine the appropriate course of action?

A. decision making
B. rapid response
C. data mining
D. due diligence

Correct Answer: A

QUESTION 6

One of the objectives of information security is to protect the CIA of information and systems.
What does CIA mean in this context?

A. confidentiality, identity, and authorization
B. confidentiality, integrity, and authorization
C. confidentiality, identity, and availability
D. confidentiality, integrity, and availability

Correct Answer: D

QUESTION 7
What is rule-based detection when compared to statistical detection?

A. proof of a user’s identity
B. proof of a user’s action
C. likelihood of user’s action
D. falsification of a user’s identity

Correct Answer: B

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