10G XGPON OLT

SOGX6292-XSGB

FEATURES

• Single fiber bi-directional data links TX 9.953Gbps/ Burst Mode RX 2.488Gbps application

• 0 to 70°C operating case temperature

• 3.3V, 5V power supply

• XFP package with SC/UPC Receptacle connector

• Hot-pluggable capability

• High power 1577nm EML DFB LD

• High sensitivity 1270nm APD

• Support 20km transmission distance with SMF

• Low EMI and excellent ESD protection

• Digital diagnostic monitor interface

• RoHS6 compliance

APPLICATIONS

• XGPON1 OLT (ODN:N2a Class)

STANDARDS

• Complies with INF-8077i

• Complies with ITU-T G.987.2

• Complies with FCC 47 CFR Part 15, Class B

• Complies with FDA 21 CFR 1040.10 and 1040.11 except for deviations pursuant to Laser Notice No. 50, dated June 24, 2007

ABSOLUTE MAXIMUM RATING

Parameter	Symbol	Min.	Max.	Unit	Notes

Storage Ambient Temperature	TSTG	-40	85	°C

Operating Case Temperature	TC	0	70	°C

Operating Humidity	OH	5	90	%

VCC3 Power Supply Voltage	VCC	0	3.6	V


VCC5 Power Supply Voltage	VCC	0	5.5	V

RECOMMENDED OPERATING CONDITION

Parameter

Symbol

Min.

Typ.

Max.

Unit

Notes

Operating Case Temperature

+70

°C

VCC3 Power Supply Voltage

VCC

3.13

3.3

3.47

VCC5 Power Supply Voltage

VCC

4.75

5.25

VCC3 Power Supply Current

ICC

1000

VCC5 Power Supply Current

ICC

500

Date Rate

9.953/2.488

Gbps

Date Rate Drift

-100

+100

PPM

TRANSMITTER OPTICAL CHARACTERISTICS

Parameter

Symbol

Min.

Typ.

Max.

Unit

Notes

Optical Center Wavelength

λ_C

1575

1580

Optical Spectrum Width (-20dB)

∆λ

Side Mode Suppression Ratio

SMSR

Average Launch Optical Power

AOP

dBm

Launched into SMF

Power-OFF Transmitter Optical Power

-39

dBm

Launched into SMF

Extinction Ratio

8.2

PRBS2³¹-1 @9.953Gbps

Transmitter Reflectance

-10

Transmitter tolerance to reflected optical

-15

power

Transmitter and Dispersion Penalty

TDP

Transmit on 20km SMF

Optical Waveform Diagram

Compliant with ITU-T 987.2

Figure 1,Mask Margin>5%

TRANSMITTER ELECTRICAL CHARACTERISTICS

Parameter

Symbol

Min.

Typ.

Max.

Unit

Notes

Data Input Differential Swing

120

820

CML input, AC coupled

Input Differential Impedance

100

110

Transmitter Disable Voltage - Low

0.8

Transmitter On

Transmitter Disable Voltage - High

2.0

VCC

Transmitter Off

Transmitter Fault Voltage - Low

0.4

Transmitter On

Transmitter Fault Voltage - High

2.4

VCC

Transmitter Fault

TRANSMITTER EYE MASK DEFINITIONS AND TEST PROCEDURE

Figure 1 XGPON Transmitter Eye Mask Definitions

X3-X2

Unit

0.2

0.25

0.75

0.25

RECEIVER OPTICAL CHARACTERISTICS

Parameter

Symbol

Min.

Typ.

Max.

Unit

Notes

Operating Wavelength

1260

1280

Sensitivity

SEN

-29.5

dBm

PRBS 2²³-1@2.488Gbps BER ≤1×10^-4

Saturation Optical Power

SAT

-9

dBm

PRBS 2²³-1@2.488Gbps BER ≤1×10^-4

Burst Dynamic Range

Loss Of Signal De-assert Level

-30

dBm

Loss Of Signal Assert Level

-45

dBm

Loss Of Signal Hysteresis

0.5

Receiver Reflectance

-20

RECEIVER ELECTRIAL CHARACTERISTICS

Parameter

Symbol

Min.

Typ.

Max.

Unit.

Notes

Receiver Amplitude Recovery Time

Trec

bit

Figure 2

Data Output Differential Swing

400

1200

CML output, DC coupled

Reset width

Trw

bits

Reset-Low

0.8

Reset-High

2.0

Vcc

Signal Detect Assert Time

Tsda

100

Signal Detect De-assert Time

Tsdd

12.8

Refer to the Reset signal rising edge

Signal Detect Voltage-Low

0.4

Signal Detect Voltage-High

2.4

Vcc

RSSI Trigger-Low

0.8

RSSI Trigger-High

2.0

Vcc

RSSI Trigger Delay

T_D

100

Figure 4

RSSI Trigger Width

T_W

350

Figure 4

I²C Access Prohibited Time

T_P

500

μs

Figure 4

TIMING PARAMETER DEFINITIONS IN BURST MODE SEQUENCE

RX input burst signals

ONU#A

ONU#B

		Trdo

RESET
	Trw	Tsda
		Tsda

	Tsdd	Undefined
		Undefined

Rx output data

Trec

Figure 2 Timing Parameter Definitions in Burst Mode Sequence

BURST MODE RECEIVER DYNAMIC RANGE

Figure 3 Burst Mode Receiver Dynamic Range in XGPON System

TIMING PARAMETER DEFINITIOINS IN RSSI TRIGGER

Figure 4 Timing Parameter Definitions in RSSI Trigger

PIN DESCRIPTION

PIN

Name

Description

Notes

GND

Module Ground

TX Fault

Transmitter Fault Indication

LVTTL, High Indicates TX Laser Fault

N.C.

Not be Connected in the transceiver

N.C.

Not be Connected in the transceiver

TX_DIS

Transmitter Disable

LVTTL, Low: transmitter on

VCC5

+5V Power Supply

GND

Module Ground

VCC3_TX

Transmitter 3.3V Power Supply

VCC3_RX

Receiver 3.3V Power Supply

SCL

The clock line

The clock line of two wire serial interface

SDA

The data line

The data line of two wire serial interface

MOD_ABS

Indicates Module is not present.

LVTTL, this pin shall be pulled-up by Host and

grounded in the module.

RX_Reset

Burst Receiver Reset

LVTTL, High level Reset

RX_SD

Receiver signal detected indication

LVTTL, high level indicates burst packet is detected

GND

Module Ground

GND

Module Ground

RD-

inverted Received Data Out

CML Output, DC coupled, Squelched by LOS

RD+

Non-inverted Received Data Out

CML Output, DC coupled, Squelched by LOS

GND

Module Ground

N.C.

Not be Connected in the transceiver

RSSI_TRIG

RSSI trigger for Transceiver A/D converter

LVTTL, High active

Not be Connected in the transceiver

GND

Module Ground

N.C.

Not be Connected in the transceiver

N.C.

Not be Connected in the transceiver

GND

Module Ground

GND

Module Ground

TX-

Inverted Transmit Data in

CML input, AC coupled

TX+

Non-Inverted Transmit Data in

CML input, AC coupled

GND

Module Ground

PIN OUT DRAWING

Figure 5 Pin Out Drawing

TYPICAL INTERFACE CIRCUIT

VCC5
	22 uF		V_ee T
	22 uF	0.1 uF	Vcc T		SOGX6292- XSGA
HOST VCC3		0.1 uF
HOST VCC3	2X4.7 uH
0. 1 uF	2X4.7 uH		Vcc R
0. 1 uF
4 .7~10K Ω	22 uF	0.1 uF	Vee R
			RX_SD
Ser Data In+		Z= 50 Ω	RD+		XGPON
Ser Data In+		Z= 50 Ω			XGPON
Ser Data In-		Z= 50 Ω	RD-		Limiting
Ser Data In-					Amplifier
					Amplifier
SerDes			RX_ Reset-
SerDes
Host Board
Ser Data Out+
Ser Data Out-			TD+
Ser Data Out+			TD+
Ser Data Out+		Z= 50 Ω
		Z= 50 Ω	TD+	100Ω
Ser Data Out-		Z= 50 Ω	TD+	100Ω	XGPON
Ser Data Out-				Vcc T	XGPON
				Vcc T	Laser
HOST V_CC					Driver
HOST V_CC			TX_DIS
	4.7～10kΩ		Tx_ fault	4.7～10kΩ
			Tx_ fault	4.7～10kΩ
HOST V_CC
	2x4.7~10K Ω		SDA			Temperature
			SCL			Temperature
			SCL			Bias Current
					MCU	Bias Current
					MCU	Supply Voltage
			RSSI-Trig			Output Power
			RSSI-Trig			Received Power
						Received Power

Figure 6 Typical Interface Circuit

PACKAGE OUTLINE

Unit: mm

Figure 7 Package Outline

EEPROM INFORMATION

Figure 8 EEPROM Memory Map Specific Data Field Descriptions

DIGITAL DIAGNOSTIC MONITORING INTERFACE

Parameter	Range	Accuracy	Calibration	Notes

Temperature	-5 to 75°C	±3°C	Internal	1LSB = 1/256°C

Voltage	3.0 to 3.6V	±3%	Internal	1LSB = 0.1mV

Bias Current	0 to 131mA	±10%	Internal	1LSB = 2uA

TX Power	0 to 8dBm	±3dB	Internal	1LSB = 0.1uW

RX Power monitor	-30 to -9dBm	±3dB	Internal	1LSB = 0.1uW

l Contact Information

Shenzhen Sinovo Telecom Co. Ltd

Website:www.sinovocorp.com Email:sales@sinovocorp.com

Tel:+86(0)0755-3295 9919 Fax:+86(0)755 3295 9918

Factory ADD: 5/F Chuang Park,Taoyuan Street,Baoan District,Shenzhen,China 518000

Head Quarter:11/F,Taibang Technology Building,Gaoxin South 4th,Science and Technology Park South,Nanshan,Shenzhen,China 518040

25G/100G-PON 进展和演进趋势分析

“宽带中国”战略首次在国家层面将宽带网络定位为“新时期我国经济社会发展的战略性公共基础设施”，宽带接入网具有投资大，建设周期长，网络复杂的突出特点，是宽带网络的主要组成部分。随着云计算、高清视频、虚拟现实等新业务的迅猛发展，用户带宽以每5-6年10倍速度增长，现有接入网技术需要不断进行升级以适应更高的带宽和技术要求。基于点到多点拓扑的PON网络是主流宽带接入技术，PON网络技术已经经历了从EPON和GPON到10G PON的发展历程。当前全球宽带接入市场逐步进入千兆时代，未来10G入户将成为宽带接入建设的必然趋势。随着4K视频和5G技术的加速发展，10G-PON技术也难以满足未来的驻地接入和移动前传和回传的带宽需求，支持25G/100G更高速率的PON技术正逐步成为业界研究热点。 1 下一代PON标准进展 10G-PON之后PON技术的演进主要有2种方式，一种是单波长速率提升，波特率由10G提升到25G/40G等;另一种是采用多波长叠加方式，每波长承载的速率是10G/25G，多波长叠加到40G/80G/100G。 FSAN 组织在2011 年启动NGPON2 的标准研发，2015年完成标准制定。FSAN 组织选择了TWDM-PON 作为主要技术方案，采用4/8波长叠加方式，每波长采用10G TDM方式，在移动回传和商业客户中可选择点对点的WDM overlay 技术。NGPON2 的关键需求主要为40G 下行和40G/10G 上行，实现20km 传输距离和1:64 分光。ITU标准组织也在关注单波25G的研究进展，预计近期将启动25G-PON的标准制定。 2013年IEEE开始启动NG-EPON研究，成立了IEEE ICCOM对NG-EPON的市场需求、技术方案进行分析，2015年3月发布了NG-EPON技术白皮书。2015年7月开始启动100G-EPON标准制定，命名为IEEE 802.3ca ，预计在2018年发布100G-EPON标准。100G-EPON目标定义了3种MAC层速率25G,50G和100G。其中25G分为非对称 10G/25G和对称25G/25G二种制式。 2 25G/100G-PON调制技术分析由于接入网技术升级快，规模巨大，投入高，高性能和低成本一直是决定接入网技术演进的关键因素。其中光器...

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