BICSI INSTALLER 1 CERTIFICATION EXAM 2025
ALL 60 QUESTIONS AND CORRECT ANSWERS
(ALREADY GRADED A+) | LATEST VERSION
Introduction
This 2025 BICSI Installer 1 simulation presents 60 original exam-grade items that
mirror the current certification blueprint:
• Cabling installation practices
• Codes, standards, and regulations
• Safety procedures
• Copper and fiber-optic testing
• Telecommunications theory
• Bonding and grounding
• Pathways and spaces
All content is written for mastery-level preparation and aligns with the 2025 BICSI
ITSIMM, ANSI/TIA-568.4-D, and applicable NEC/CSA requirements. No question
duplicates proprietary BICSI material.
Question 1
When installing a 4-pair Category 6A UTP cable horizontally above a factory floor with
480 V motor drives, the minimum separation distance (no divider) per TIA-569-E is:
A. 300 mm
B. 600 mm
C. 1,000 mm
D. 50 mm
Answer: B. 600 mm
Solution: TIA-569-E Table 4.3 specifies 600 mm (24 in.) between communications
cables and power >300 V to <600 V when no physical barrier is used. 300 mm is for
power <300 V; 1,000 mm is not listed; 50 mm is for screened power within the same
tray.
Question 2
A 50/125 µm laser-optimized multimode fiber must support 40 GbE (40GBASE-SR4)
over 150 m. The highest OM rating acceptable is:
pg. 1
,A. OM2
B. OM3
C. OM4
D. OM5
Answer: C. OM4
Solution: OM4 is specified to 150 m for 40GBASE-SR4. OM3 only reaches 100 m; OM2 is
insufficient (≤50 m); OM5 supports the distance but is not the highest acceptable
rating—OM4 already meets the requirement.
Question 3
During a pull of 24-fiber indoor/outdoor cable, the tensile load gauge reads 800 N.
Manufacturer’s maximum pulling tension is 2,500 N. The correct action is:
A. Increase pulling speed to reduce friction heat
B. Continue; tension is within spec
C. Reduce pulling force to ≤600 N and use additional lubricant
D. Reverse the pull to redistribute stress
Answer: B. Continue; tension is within spec
Solution: 800 N < 2,500 N limit—no violation. Increasing speed (A) risks burn-
through; reducing to 600 N (C) is unnecessary; reversing (D) wastes time and may kink
cable.
Question 4
Which tool is primary for verifying proper blade depth when preparing 900 µm tight-
buffered fiber for mechanical splice?
A. Visual fault locator (VFL)
B. Fiber cleave inspection microscope
C. Buffer strip gauge
D. OTDR
Answer: C. Buffer strip gauge
Solution: The buffer strip gauge (or factory strip-length template) ensures correct
buffer removal without nicking fiber. Microscope (B) checks cleave quality; VFL (A)
checks continuity; OTDR (D) is for end-to-end characterization.
Question 5
A copper cable run between two buildings (different electrical services) exhibits 60 V AC
between shield and building ground. The first safety step is:
A. Isolate the shield at one end
B. Bond the shield to the main earthing bar immediately
pg. 2
, C. De-energize and verify absence of voltage before handling
D. Apply dielectric grease to the connector
Answer: C. De-energize and verify absence of voltage before handling
Solution: Treat as energized circuit—lock-out/tag-out first. Bonding (B) might create
arc flash; isolation (A) is corrective but not first safety action; grease (D) is irrelevant.
Question 6
The minimum cover depth for direct-buried communications cable under a residential
concrete driveway per NEC 2025 Table 300.5 is:
A. 300 mm (12 in.)
B. 450 mm (18 in.)
C. 600 mm (24 in.)
D. 100 mm (4 in.)
Answer: B. 450 mm (18 in.)
Solution: NEC 300.5 specifies 450 mm (18 in.) under driveways not subject to truck
traffic. 600 mm is for public streets; 300 mm is for yard areas without vehicles; 100 mm
is insufficient.
Question 7
A continuity test on a Cat 6 horizontal run shows 6.0 Ω end-to-end on conductor #4. The
maximum allowable per TIA-1152A is:
A. 5 Ω
B. 10 Ω
C. 25 Ω
D. 0.1 Ω
Answer: A. 5 Ω
Solution: TIA-1152A clause 6.2.2 sets 5 Ω maximum DC resistance for any 100 m
horizontal conductor. 10 Ω and 25 Ω are obsolete specs; 0.1 Ω is typical for patch cords
only.
Question 8
When fusion-splicing ribbon fiber, the most critical parameter monitored by the
splicer’s PAS (profile alignment system) is:
A. Core concentricity error
B. Cladding diameter mismatch
C. Fiber curl radius
D. Cleave angle deviation
pg. 3
ALL 60 QUESTIONS AND CORRECT ANSWERS
(ALREADY GRADED A+) | LATEST VERSION
Introduction
This 2025 BICSI Installer 1 simulation presents 60 original exam-grade items that
mirror the current certification blueprint:
• Cabling installation practices
• Codes, standards, and regulations
• Safety procedures
• Copper and fiber-optic testing
• Telecommunications theory
• Bonding and grounding
• Pathways and spaces
All content is written for mastery-level preparation and aligns with the 2025 BICSI
ITSIMM, ANSI/TIA-568.4-D, and applicable NEC/CSA requirements. No question
duplicates proprietary BICSI material.
Question 1
When installing a 4-pair Category 6A UTP cable horizontally above a factory floor with
480 V motor drives, the minimum separation distance (no divider) per TIA-569-E is:
A. 300 mm
B. 600 mm
C. 1,000 mm
D. 50 mm
Answer: B. 600 mm
Solution: TIA-569-E Table 4.3 specifies 600 mm (24 in.) between communications
cables and power >300 V to <600 V when no physical barrier is used. 300 mm is for
power <300 V; 1,000 mm is not listed; 50 mm is for screened power within the same
tray.
Question 2
A 50/125 µm laser-optimized multimode fiber must support 40 GbE (40GBASE-SR4)
over 150 m. The highest OM rating acceptable is:
pg. 1
,A. OM2
B. OM3
C. OM4
D. OM5
Answer: C. OM4
Solution: OM4 is specified to 150 m for 40GBASE-SR4. OM3 only reaches 100 m; OM2 is
insufficient (≤50 m); OM5 supports the distance but is not the highest acceptable
rating—OM4 already meets the requirement.
Question 3
During a pull of 24-fiber indoor/outdoor cable, the tensile load gauge reads 800 N.
Manufacturer’s maximum pulling tension is 2,500 N. The correct action is:
A. Increase pulling speed to reduce friction heat
B. Continue; tension is within spec
C. Reduce pulling force to ≤600 N and use additional lubricant
D. Reverse the pull to redistribute stress
Answer: B. Continue; tension is within spec
Solution: 800 N < 2,500 N limit—no violation. Increasing speed (A) risks burn-
through; reducing to 600 N (C) is unnecessary; reversing (D) wastes time and may kink
cable.
Question 4
Which tool is primary for verifying proper blade depth when preparing 900 µm tight-
buffered fiber for mechanical splice?
A. Visual fault locator (VFL)
B. Fiber cleave inspection microscope
C. Buffer strip gauge
D. OTDR
Answer: C. Buffer strip gauge
Solution: The buffer strip gauge (or factory strip-length template) ensures correct
buffer removal without nicking fiber. Microscope (B) checks cleave quality; VFL (A)
checks continuity; OTDR (D) is for end-to-end characterization.
Question 5
A copper cable run between two buildings (different electrical services) exhibits 60 V AC
between shield and building ground. The first safety step is:
A. Isolate the shield at one end
B. Bond the shield to the main earthing bar immediately
pg. 2
, C. De-energize and verify absence of voltage before handling
D. Apply dielectric grease to the connector
Answer: C. De-energize and verify absence of voltage before handling
Solution: Treat as energized circuit—lock-out/tag-out first. Bonding (B) might create
arc flash; isolation (A) is corrective but not first safety action; grease (D) is irrelevant.
Question 6
The minimum cover depth for direct-buried communications cable under a residential
concrete driveway per NEC 2025 Table 300.5 is:
A. 300 mm (12 in.)
B. 450 mm (18 in.)
C. 600 mm (24 in.)
D. 100 mm (4 in.)
Answer: B. 450 mm (18 in.)
Solution: NEC 300.5 specifies 450 mm (18 in.) under driveways not subject to truck
traffic. 600 mm is for public streets; 300 mm is for yard areas without vehicles; 100 mm
is insufficient.
Question 7
A continuity test on a Cat 6 horizontal run shows 6.0 Ω end-to-end on conductor #4. The
maximum allowable per TIA-1152A is:
A. 5 Ω
B. 10 Ω
C. 25 Ω
D. 0.1 Ω
Answer: A. 5 Ω
Solution: TIA-1152A clause 6.2.2 sets 5 Ω maximum DC resistance for any 100 m
horizontal conductor. 10 Ω and 25 Ω are obsolete specs; 0.1 Ω is typical for patch cords
only.
Question 8
When fusion-splicing ribbon fiber, the most critical parameter monitored by the
splicer’s PAS (profile alignment system) is:
A. Core concentricity error
B. Cladding diameter mismatch
C. Fiber curl radius
D. Cleave angle deviation
pg. 3
