Lesson 5/PT = 0x21/Summary ODUj Tributary Signal Mapping/Multiplexing into an ODU2 Server Signal

This blog post includes a video that Summarizes our Training on Mapping/Multiplexing ODUj Tributary Signals into an ODU2 Server Signal.

Summary/Review – Mapping/Multiplexing ODUj Tributary Signals into an ODU2 Server Signal (PT = 0x21)

This blog post includes a video that summarizes our training on Mapping/Multiplexing ODUj Tributary Signals into an ODU2 Server Signal, using the PT = 0x21 Approach.

In particular, we briefly summarize the following topics within this video.

  • A quick review of Mapping/Multiplexing schemes that use GMP (Generic Mapping Procedure)
  • A quick review of Mapping/Multiplexing schemes that use AMP (Asynchronous Mapping Procedure)
  • Mapping and Multiplexing as many as 8 ODU0 Tributary Signals into an ODU2 Server Signal
  • Mapping and Multiplexing as many as 4 ODU1 Tributary Signals into an ODU2 Server Signal
  • Also Mapping and Multiplexing some number of ODUflex Tributary Signals into an ODU2 Server Signal.
  • A Discussion on why we logically subdivide ODU1 and ODUflex tributary signals into time-slots (when mapping/multiplexing into a Higher-Speed ODUk Server Signal) but we don’t do that for ODU0 tributary signals.
  • A Review of the MSI (Multiplex Structure Identifier) within the ODU2 Server Signal for each of these Mapping/Multiplexing Schemes.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/Summary ODUj Tributary Signal Mapping/Multiplexing into an ODU2 Server Signal”

Lesson 5/PT = 0x21/4 ODU1 – Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal

This blog post includes a video that shows how we can map/multiplex as many as 4 ODU1 Tributary Signals into an ODU2 Server Signal, using the PT = 0x21 Scheme.

Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal (PT = 0x21)

This blog post includes a video that:

  • Shows how we map and multiplex as many as 4 ODU1 Tributary Signals into an ODU2 Server Signal, using the PT = 0x21 Approach.

In this video, we discuss the following:

  • Mapping/Multiplexing 4 ODU1 Signals into an ODU2 Server Signal using the PT = 0x21 Approach differs from doing the same via the PT = 0x20 Approach.
  • Using the AMP (Asynchronous Mapping Procedure) to map each ODU1 Tributary signal into their respective ODTU12 signal/frames.
  • How to combine these ODTU12 signals and map them into an ODU2 payload.
  • Transporting these AMP Justification parameters from the Source PTE (where we map/multiplex these ODU1 tributary signals into an ODU2 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU1 tributary signals)
  • A review of the Multiplex Structure Identifier (MSI) within this type of ODU2 signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/4 ODU1 – Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal”

Lesson 5/PT = 0x21/Summary ODUj Tributary Signal Mapping/Multiplexing into an ODU3 Server Signal

This blog post contains a video that summarizes our training on Mapping/Multiplex ODUj Tributary Signals into an ODU3 Server Signal, using the PT = 0x21 Scheme.

Summary/Review – Mapping/Multiplexing ODUj Tributary Signals into an ODU3 Server Signal (PT = 0x21)

This blog post includes a video that summarizes our training on Mapping/Multiplexing ODUj Tributary Signals into an ODU3 Server Signal, using the PT = 0x21 Approach.

In particular, we briefly summarize the following topics within this video.

  • A quick review of Mapping/Multiplexing schemes that use GMP (Generic Mapping Procedure)
  • A quick review of Mapping/Multiplexing schemes that use AMP (Asynchronous Mapping Procedure)
  • Mapping and Multiplexing as many as 32 ODU0 Tributary Signals into an ODU3 Server Signal
  • Mapping and Multiplexing as many as 16 ODU1 Tributary Signals into an ODU3 Server Signal
  • Also, Mapping and Multiplexing as many as 4 ODU2 Tributary Signals into an ODU3 Server Signal.
  • Mapping and Multiplexing as many as 3 ODU2e Tributary Signals into an ODU3 Server Signal
  • Mapping and Multiplexing some number of ODUflex Tributary Signals into an ODU3 Server Signal
  • A Discussion on why we logically subdivide ODU1, ODU2, ODU2e, and ODUflex tributary signals into time-slots (when mapping/multiplexing into a Higher-Speed ODUk Server Signal), but we don’t do that for ODU0 tributary signals.
  • A Review of the MSI (Multiplex Structure Identifier) within the ODU3 Server Signal for each Mapping/Multiplexing Schemes.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/Summary ODUj Tributary Signal Mapping/Multiplexing into an ODU3 Server Signal”

Lesson 5/PT = 0x21/3 ODU2e – Mapping/Multiplexing 3 ODU2e Tributary Signals into an ODU3 Server Signal

This post describes how we map/multiplexing as many as 3 ODU2e tributary signals into an ODU3 server signal, using the PT = 0x21 Approach.

Mapping/Multiplexing 3 ODU2e Tributary Signals into an ODU3 Server Signal (PT = 0x21)

This blog post includes a video that shows how we map and multiplex as many as 3 ODU2e Tributary Signals into an ODU3 Server Signal, using the PT = 0x21 Approach.

In particular, we discuss the following topics in this video.

  1. Subdividing the ODU2e signal into nine (9) separate 1.25 Gbps time-slots.
  2. Using the GMP (Generic Mapping Procedure) to map the ODU2e tributary signal into their ODTU3.9 signal/frames.
  3. How to combine these ODTU3.9 signals (along with other signals, such as ODTU3.1 and ODTU13 signals) into an ODU3 payload.
  4. Transporting the GMP Justification parameters from the Source PTE (where we map/multiplex these ODU2e tributary signals into an ODU3 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU2e tributary signals).
  5. Multiplex Structure Identifiers within this type of ODU3 server signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/3 ODU2e – Mapping/Multiplexing 3 ODU2e Tributary Signals into an ODU3 Server Signal”

Lesson 5/PT = 0x21/4 ODU2 – Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal

This post describes how we map/multiplex as many as 4 ODU2 tributary signals into an ODU3 server signal using the PT = 0x21 Approach.

Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal (PT = 0x21)

This blog post includes a video that:

  • Shows how we map and multiplex as many as 4 ODU2 Tributary Signals into an ODU3 Server Signal, using the PT = 0x21 Approach.

In particular, we discuss the following topics in this video.

  • Subdividing the ODU2 signal into eight (8) separate 1.25 Gbps time-slots.
  • Using the AMP (Asynchronous Mapping Procedure) to map the ODU2 tributary signal into their respective ODTU23 signal/frames.
  • Steps on How to combine these ODTU23 signals and map them into an ODU3 payload.
  • Transporting the AMP Justification parameters from the Source PTE (where we map/multiplex these ODU2 tributary signals into an ODU3 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU2 tributary signals).
  • Multiplex Structure Identifiers within this type of ODU3 server signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/4 ODU2 – Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal”

Lesson 5/PT = 0x21/16 ODU1 – Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal

This post describes how we map/multiplex as many as 16 ODU1 tributary signals into an ODU3 sever signal.

Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal (PT = 0x21)

This blog post includes a video that:

  • Shows how we map and multiplex as many as 16 ODU1 Tributary Signals into an ODU3 Server Signal, using the PT = 0x21 Approach.

In particular, we discuss the following topics in this video.

  • Subdividing the ODU1 signal into two separate 1.25 Gbps time-slots.
  • Using the AMP (Asynchronous Mapping Procedure) to map the ODU1 tributary signals into their respective ODTU13 signal/frames.
  • How to combine these ODTU13 signals and map them into an ODU3 payload.
  • Transporting these AMP Justification parameters from the Source PTE (where we map/multiplex these ODU1 tributary signals into an ODU3 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU1 tributary signals).
  • Multiplex Structure Identifiers within this type of ODU3 server signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x21/16 ODU1 – Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal”

Lesson 5/PT = 0x20/16 ODU1 – Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal

This blog post presents a video that shows how to map/multiplexing as many as 16 ODU1 tributary signals into an ODU3 server signal, using the PT = 0x20 approach.

Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal (PT = 0x20)

This blog post includes a video that shows how we map and multiplex as many as 16 ODU1 Tributary Signals into an ODU3 Server Signal, using the PT = 0x20 Approach.

In this video, we discuss the following:

  • Using the AMP (Asynchronous Mapping Procedure) to map the ODU1 tributary signals into their respective ODTU13 signal/frames.
  • How to combine these ODTU13 signals and map them into an ODU3 payload.
  • Transporting these AMP Justification parameters from the Source PTE (where we map/multiplex these ODU1 tributary signals into the ODU3 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU1 tributary signals).
  • Multiplex Structure Identifiers within this type of ODU3 signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x20/16 ODU1 – Mapping/Multiplexing 16 ODU1 Tributary Signals into an ODU3 Server Signal”

Lesson 5/PT = 0x20/4 ODU2 – Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal

This blog post presents a video on how to map/multiplex as many as 4 ODU2 tributary signals into an ODU3 server signal, using the PT = 0x20 approach.

Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal using the PT = 0x20 Scheme.

This blog post includes a video that shows how we map and multiplex as many as 4 ODU2 Tributary Signals into an ODU3 Server Signal, using the PT = 0x20 Scheme.

In this video, we discuss the following:

  • Sub-dividing an ODU2 tributary signal into its 2.5 Gbps time-slots.
  • Use the AMP (Asynchronous Mapping Procedure) to map each ODU2 tributary signal into an ODTU23 signal/frame.
  • How to combine these ODTU23 signals and map them into an ODU3 payload.
  • Transporting the AMP Justification Parameters from the Source PTE (where we map/multiplex the ODU2 tributary signals into the ODU3 server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU2 tributary signals).
  • The Multiplex Structure Identifiers within this type of ODU3 signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x20/4 ODU2 – Mapping/Multiplexing 4 ODU2 Tributary Signals into an ODU3 Server Signal”

Lesson 5/PT = 0x20, Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal.

This blog post presents a video on how to map/multiplex as many as four ODU1 tributary signals into an ODU2 server signal, using the PT = 0x20 approach.

Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal using the PT = 0x20 Approach

This blog post includes a video that shows how we map and multiplex as many as 4 ODU1 Tributary Signals into an ODU2 Server Signal, using the PT = 0x20 Approach.

In this video, we discuss the following:

  • Using the AMP (Asynchronous Mapping Procedure) to map the ODU1 tributary signals into the ODTU12 signals/frames.
  • How to combine the ODTU12 signals and then map them into an ODU2 payload.
  • Transporting the AMP Justification parameters from the Source PTE (where we map/multiplex the ODU1 signals into the ODU2 Server signal) to the Sink PTE (where we de-multiplex and de-map out the ODU1 tributary signals).
  • Multiplex Structure Identifiers within this type of ODU2 signal.

You can view this video below.

Continue reading “Lesson 5/PT = 0x20, Mapping/Multiplexing 4 ODU1 Tributary Signals into an ODU2 Server Signal.”

Lesson 5 – PT = 0x20 Approach

This blog post provides information and Video Training on the PT = 0x20 Approach for Mapping/Multiplexing Lower-Speed ODUj Tributary Signals into an ODUk Server Signal.

Lesson 5 – PT = 0x20 Approach to Mapping/Multiplexing Lower-Speed ODUj Tributary Signals into an ODUk Server Signal.

This portion of Lesson 5 presents information, along with a Training Video on how we Map and Multiplex Lower-Speed ODUj Tributary Signals into a Higher-Speed ODUk Server Signal using the PT = 0x20 Approach.

This Lesson includes four (4) videos discussing mapping/multiplexing lower-speed ODUj Tributary Signals into an OPUk/ODUk Server Signal using the PT = 0x20 scheme.

Introduction to the PT = 0x20 Scheme and Mapping/Multiplexing up to 2 ODU0 Tributary Signals into an ODU1 Server Signal

This video covers the following topics.

  • An overall discussion of the PT = 0x20 Scheme to Mapping and Multiplexing Lower-Tributary ODUj signals into an ODUk Server signal.
  • How do we use the PT =0x20 Approach to mapping/multiplexing 2 ODU0 signals into an ODU1 server signal? As this video discusses this particular mapping/multiplexing scheme, it will cover the following items in detail.
    • Using the AMP (Asynchronous Mapping Procedure) to map each ODU0 tributary signal into an ODTU01 frame/signal.
    • How do we combine each ODTU01 signal and map this data into the ODU1 payload?
    • Transporting these AMP Justification parameters from the Source PTE (where we map/multiplex these ODU0 tributary signals into the ODU1 server signal) and the Sink PTE (where we de-multiplex and de-map out the ODU0 tributary signals).
    • The Multiplexed Structure Identifier within this type of ODU1 server signal.

You can watch the Video Training that Introduces the PT = 0x20 Scheme and discusses Mapping/Multiplexing up to 2 ODU0 Tributary Signals into an ODU1 Server below.

Continue reading “Lesson 5 – PT = 0x20 Approach”