In color television systems, how are the chrominance subcarrier and its sidebands fitted into the standard channel bandwidth without severe interference to the luminance spectrum?
-
AFrequency adjustment
-
BFrequency interleaving
-
CFrequency changing
-
DFrequency amalgamation
-
ETime-division blanking
Answer
Correct Answer: Frequency interleaving
Explanation
Introduction / Context:Color TV adds chrominance information via a subcarrier and sidebands to an existing luminance signal within a fixed channel width. Clever spectral placement prevents visible cross-talk patterns while maintaining compatibility with monochrome receivers.
Given Data / Assumptions:
- Chrominance is modulated onto a subcarrier (e.g., PAL ~4.43 MHz).
- Luminance spectrum contains strong line-rate harmonics.
- Goal: fit chroma within the same channel without objectionable interference.
Concept / Approach:
Frequency interleaving places the subcarrier at a frequency offset such that its sidebands fall between dominant luminance spectral lines (which are concentrated at multiples of half the line frequency), effectively interleaving spectra and reducing cross-luminance and cross-color artifacts.
Step-by-Step Solution:
Recognize the line-locked nature of luminance spectral lines.Choose subcarrier frequency related to half the line frequency to interleave chroma.Result: chroma sidebands occupy spectral valleys between luminance components.Verification / Alternative check:
PAL/NTSC design uses subcarrier frequencies carefully tied to line frequency fractions (e.g., 283.75 * f_H in NTSC) to achieve interleaving.
Why Other Options Are Wrong:
- “Adjustment/Changing/Amalgamation” are vague and do not capture the line-locked interleaving principle.
- Time-division techniques are not how analog color subcarrier coexists in the channel.
Common Pitfalls:
Assuming simple filtering suffices; in reality, precise frequency planning is essential for compatibility and artifact control.
Final Answer:
Frequency interleaving