What is the difference between GPON and EPON?

GPON offers higher downstream bandwidth and better QoS. EPON provides symmetric bandwidth at lower cost. GPON supports split ratios up to 1:128 for wider coverage.

Which ONU/ONT is compatible with my OLT?

Our L880G and L801 series ONUs support XPON dual-mode and work with Huawei, ZTE, FiberHome and other major OLT brands. Contact support to confirm compatibility.

What is the difference between SC/APC and SC/UPC connectors?

SC/APC (Angled Physical Contact) and SC/UPC (Ultra Physical Contact) are two common fiber optic connector polish types. The key difference is the end-face angle.SC/UPC: Flat end-face with slight curve, return loss ≥50dB. Used for general-purpose data transmission. Blue color.SC/APC: 8° angled end-face, return loss ≥60dB. Used for RF video transmission (CATV) and PON networks. Green color.They are NOT interchangeable — mixing them can damage the connector end-face.

How do I choose the right fiber optic splitter for my network?

Choosing the right fiber optic splitter depends on several factors:Type: PLC splitters offer better performance for FTTx; FBT splitters suit smaller setupsRatio: Common ratios: 1×2, 1×4, 1×8, 1×16, 1×32, 1×64Package: ABS box (indoor), Mini steel tube (tight spaces), LGX cassette (rack mount)Connector: SC/APC for CATV, SC/UPC for dataFor GPON/EPON FTTH deployments, a 1×8 or 1×16 PLC splitter with SC/APC connectors is recommended.

What is the maximum distance for fiber optic transmission?

Fiber optic transmission distance depends on fiber type and equipment:Single-mode fiber (OS2): Up to 40km+ without amplificationMulti-mode fiber (OM1-OM5): 300m to 550m at 10GbpsGPON: Typically 20km reachEPON: Typically 20kmXGS-PON: Up to 40km1550nm wavelength has lower attenuation (≈0.2dB/km) vs 1310nm (≈0.35dB/km). For standard GPON FTTH, 20km is typical from OLT to ONU.

How do I configure an ONU/ONT for my fiber network?

Configuring an ONU/ONT involves these steps:Connect: Plug fiber cable into PON port, Ethernet to your router/PCPower on: Wait for PON LED to turn solid (optical signal received)Access web: Set PC to same subnet (192.168.1.x), open ONU IP (usually 192.168.1.1)Configure WAN: Set connection type (PPPoE, DHCP, or Static IP) per ISP requirementsRegister: Some ISPs require registration via serial number, LOID password, or MAC address

What is XGS-PON and how is it different from GPON?

XGS-PON (10 Gigabit Symmetric PON) is the next-generation PON technology offering 10Gbps symmetric bandwidth. Key differences from GPON:Speed: GPON = 2.5Gbps down / 1.25Gbps up. XGS-PON = 10Gbps both directionsWavelength: XGS-PON uses 1577nm down / 1270nm up (different from GPON's 1490nm/1310nm)Coexistence: XGS-PON can share the same fiber with GPON via WDMXGS-PON ONUs work with dual-mode OLTs but need an XGS-PON port for 10G speeds. Ideal for 4K/8K streaming, cloud computing, and enterprise use.

How Many Homes Can One OLT Port Serve?

In GPON networks, one OLT port typically serves 32 to 128 homes, depending on the split ratio. A 1:32 splitter is most common for FTTH deployments. With XGS-PON, one port can serve 256+ subscribers. Actual capacity depends on bandwidth per user — if each user needs 100Mbps, a GPON port (2.5Gbps down) handles ~25 users at peak. For our 2-port EPON OLT (L202), each port supports up to 64 ONUs, giving a total of 128 homes per device.

How Is GPON Data Secured on Fiber Optic Networks?

GPON uses AES-128 encryption to secure downstream data. Each ONU receives only its own data — the OLT encrypts traffic with a unique key per ONU. Upstream data is inherently secure because each ONU transmits in its assigned time slot. AES encryption is enabled by default in most OLTs like our EPON/GPON models. For additional security, MAC address filtering and ONU authentication are supported.

Is Fiber Optic Cheaper Than Copper in the Long Run?

Yes. While fiber optic cabling costs 20-30% more upfront, its total cost of ownership (TCO) over 10 years is 40-60% lower than copper. Fiber supports 40Gbps+ bandwidth vs copper's 10Gbps limit, has 25+ year lifespan (copper: 5-10 years), and needs no signal repeaters for up to 40km. For ISPs, the breakeven point is typically 2-3 years. Our single-mode fiber patch cables and splitters provide reliable long-term infrastructure.

PON Network Design Guide | GPON Architecture Tutorial

## What is a PON Network?

A PON is a point-to-multipoint fiber architecture where a single optical fiber from the provider's central office serves multiple subscribers through passive optical splitters. "Passive" means no powered equipment between the central office and the customer — only optical splitters, which dramatically reduces maintenance and power costs compared to active Ethernet networks.

```

OLT (Central Office) → Feeder Fiber → Splitter → Distribution Fiber → ONU (Customer)

```

## Layer 1: The Optical Distribution Network (ODN)

The physical fiber plant is the most expensive part of any PON deployment and the hardest to change later. Get this right.

### Splitter Placement: Centralized vs Distributed

| Architecture | Splitter Location | Best For |

|:-------------|:-----------------|:---------|

| Centralized (1-stage) | All splitters at central office or FDH | Low fiber count, easy maintenance |

| Distributed (2-stage) | First split at FDH, second near customers | Saves feeder fiber, harder to troubleshoot |

For most greenfield deployments, a **two-stage distributed architecture** with a 1x4 first split and 1x8 second split (total 1:32) offers the best balance of fiber efficiency and manageable optical budget.

### Optical Power Budget

A standard GPON Class B+ link budget is 28 dB. Here's where it goes:

|:----------|:------------:|:-----:|:-----:|

| 1x4 Splitter (1st stage) | 7.2 dB | 1 | 7.2 dB |

| 1x8 Splitter (2nd stage) | 10.5 dB | 1 | 10.5 dB |

| G.652 Fiber (feeder) | 0.35 dB/km | 5 km | 1.75 dB |

| G.652 Fiber (distribution) | 0.35 dB/km | 3 km | 1.05 dB |

| Connectors (4 pairs) | 0.5 dB | 4 | 2.0 dB |

| Splices (6 points) | 0.1 dB | 6 | 0.6 dB |

| **Total Loss** | | | **23.1 dB** |

| **Remaining Margin** | | | **4.9 dB** ✅ |

With 4.9 dB margin, this design passes comfortably. If margin drops below 3 dB, consider reducing the split ratio or shortening fiber runs.

## Layer 2: GPON Frame Structure

GPON uses two wavelengths:

- **1490nm downstream** (OLT → ONU): 2.488 Gbps, broadcast to all ONUs

- **1310nm upstream** (ONU → OLT): 1.244 Gbps, TDMA (time-division multiple access)

Each ONU is assigned time slots for upstream transmission. The OLT's DBA (Dynamic Bandwidth Allocation) algorithm distributes upstream bandwidth based on:

- **Fixed bandwidth:** Guaranteed minimum (e.g., VoIP: 100 Kbps)

- **Assured bandwidth:** Minimum with ability to borrow excess

- **Non-assured bandwidth:** Best-effort, no guarantee

- **Best-effort:** Lowest priority (P2P, background downloads)

## Planning for Subscriber Density

|:----------|:------------:|:-----------------:|:-----------------:|

| Rural | <50 | 1x8 or 1x16 | 16-32 |

| Suburban | 50-500 | 1x32 | 64-128 |

| Urban | 500-2,000 | 1x32 or 1x64 | 128-256 |

| High-rise/MDU | >2,000 | 1x64 (one per building) | 256-512 |

**Rule of thumb:** Don't exceed 70% utilization per PON port. If you have a 1x32 splitter serving 32 homes, plan the OLT capacity assuming only 22 will be active simultaneously during peak hours.

## Capacity Planning Example

You're building a network for 5,000 subscribers in a suburban area:

1. Choose 1x32 splitters → 5,000 / 32 = 157 splitters needed

2. Each PON port serves one splitter → 157 PON ports needed

3. OLT with 16 PON ports per card → 10 cards needed

4. Each OLT chassis holds 8 cards → 2 chassis needed

5. Uplink bandwidth: 157 × 2.5 Gbps × 70% utilization = 275 Gbps

Budget for at least 2 × 40GE or 4 × 100GE uplinks to the core network.

## VLAN Planning

Proper VLAN design prevents broadcast storms and enables per-subscriber service differentiation:

| VLAN Range | Service | Priority |

|:-----------|:--------|:--------|

| 100-199 | Internet (per subscriber) | 0 (best-effort) |

| 200-299 | IPTV (multicast) | 4 |

| 300-399 | VoIP | 5 (EF) |

| 400-499 | Management / TR-069 | 6 |

## Redundancy Considerations

PON is inherently single-path — a fiber cut between the splitter and ONU takes that subscriber offline. Options for adding redundancy:

- **Type B protection:** Dual feeder fibers from OLT to splitter with automatic switchover

- **GPON ring topology:** Optical switches create a self-healing ring at the splitter level

- **Wireless backup:** 4G/5G failover at the ONU for critical customers (hospitals, emergency services)

For residential ISPs, Type B protection on the feeder fiber is the most cost-effective redundancy layer. It adds ~20% to the OLT cost but protects against the most common single point of failure.

## Common Design Mistakes

1. **Underestimating fiber loss** — Always measure, never calculate from datasheet alone. Real-world connectors average 0.5-0.8 dB, not 0.3 dB.

2. **No expansion planning** — Leave 20% spare ports on every splitter and OLT card

3. **Ignoring temperature** — Outdoor splitters in enclosures can reach 60°C in summer. Use industrial-temperature (-40°C to +85°C) splitters for outdoor deployments

4. **Forgetting documentation** — Label every fiber at both ends. An unlabeled 144-fiber cable is a career-limiting move

## Quick Start Checklist

- [ ] Site survey completed with fiber path map

- [ ] Splitter placement decided (centralized or distributed)

- [ ] Optical budget calculated (minimum 3 dB margin)

- [ ] VLAN plan documented

- [ ] OLT chassis and PON port count specified

- [ ] Redundancy strategy defined

- [ ] All fibers labeled

For PON network equipment — including GPON OLTs, PLC splitters, and ONU devices — [Langzhi Technology](https://www.langzhichina.com) provides pre-configured solutions with OLT-ONU compatibility testing for faster deployment.

PON Network Design for Beginners: GPON Architecture, Planning and Deployment Guide