F2410 FOM II Series E1 Fiber Optic Modem Technical Manual

1. You call VERSITRON at 302-894-0699 or 800-537-2296 and obtain a Return Maintenance Authorization (RMA) Number. Please reference your RMA number on the outside of box in which the item is shipped.

No other warranty is expressed or implied and we are not liable for consequential damages. For repairs outside of the warranty period, the same procedure must be followed.

SECTION 1: DESCRIPTION OF EQUIPMENT

SECTION 2: INSTALLATION

SECTION 3: OPERATION

SECTION 4: THEORY OF OPERATION

SECTION 5: MAINTENANCE AND TROUBLESHOOTING

List of ILLUSTRATIONS

List of TABLES

SECTION 1

DESCRIPTION OF EQUIPMENT

1.1 INTRODUCTION

This manual provides information on the installation and operation of the Model F2410 FOM II Series E1 Fiber Optic Modem. Section 1 contains a general description of the equipment. Section 2 contains installation instructions. Section 3 contains operating instructions. Section 4 provides the theory of operation. Section 5 contains maintenance and troubleshooting information.

Model Number	Part Number	Description
F2412	30283-12	E1 fiber modem, duplex or simplex, 850nm MM LED, ST, 3km
F2414	30283-14	E1 fiber modem, duplex or simplex, 1300nm MM LED, ST, 15km
F2415	30283-15	E1 fiber modem, duplex or simplex, 1300nm SM LED, ST, 30km

1.2 DESCRIPTION OF EQUIPMENT

1.2.1 Functional Characteristics

The Model F2410 FOM II Series products are fiber optic links designed for use as an E1-standard fiber optic modem. F2410 modems use fiber optic cable of up to 3km (1.85mi/9,800ft) for 850nm multimode LEDs, up to 15km (9.3mi/49,000ft) for 1300nm multimode LEDs, or 30km (18.6mi/ 98,000ft) for 1300nm single mode LEDs. The fiber optic circuit (two F2410 modems connected by fiber optic cable) has data rates and electrical signal characteristics that conform to G.703, G.823, and G.955 standards. Electrical signals on copper cable are converted to fiber optic signals by the F2410 modem, and AMI or HDB3 data protocols are decoded.

1.2.2 Physical Characteristics

F2410 modems measure 7.0W x 0.84H x 11.6L in. (17.8 x 2.1 x 28.9 cm) and are designed for mounting in a variety of VERSITRON enclosures or chassis. Table 1 lists dimensions of enclosures and chassis. Standalone options include single card enclosures (HF-1) and dual card enclosures (HF-2). Rack mount options include 2-slot chassis (HF-2SS) and 20-slot chassis (HF-20). Each F2410 installed in a HF-1, HF-2 or HF-2SS requires either a VERSITRON Model PSAC08 (US) or PSAC09 (European) power adapter providing 12 VDC, 1A with a one-pin connector for electrical input on the back of the modem. There is a female DB15 subminiature connector for the digital interface and two ST connectors for the fiber optic interface, also on the back of the modem. F2410 modems installed in a HF-20 require a Model AC150W Power Supply / System Monitor. Each AC150W installed into the HF-20 requires two slots. Two AC150W power supplies are required for redundancy. The F2410 modems have six LED indicators on the front panel: DC power on (PWR), alarm (ALM), transmit data present (TXD), receive data present (RXD), bipolar violation (BPV), and loopback mode indicator (LOOP).

Model # (Part #)	Dimensions	Description	*Power Supply Required ¹**
HF-1 (19052)	7.1" W x 1.3" H x 11.6" L	Single Card Standalone Enclosure	PSAC08 PSAC09 (LTWPD1210PLX) (LTWPD1210EPL)
HF-2 *² (19053)	7.1" W x 2.3" H x 11.6" L	Dual Card Standalone Enclosure	PSAC08 PSAC09 (LTWPD1210PLX) (LTWPD1210EPL)
HF-2SS *² (19629)	19" W x 1.7" H x 13.8" L	2-Slot Rack Mount Chassis	PSAC08 PSAC09 (LTWPD1210PLX) (LTWPD1210EPL)
HF-20 (19032)	19" W x 7.1" H x 11.6" L	20-Slot Rack Mount Chassis	AC150W (19320-03)

*¹ Note: US Model - PSAC08; European Model - PSAC09

*² Note: One Power Supply per Modem required.

TABLE 1. ENCLOSURES / CHASSIS

1.3 SPECIFICATIONS

Power Requirements: HF-1, HF-2, or HF-2SS Installation: VAC source with optional PSAC08 (US) or PSAC09 (European) power adapter providing 12 VDC, 1A. HF-20 Installation: Model AC150W Power Supply / System Monitor (110/250 VAC, ±10%; 47-63 Hz (auto-selecting)).

Environment: 0° to +50°C (32° to +122°F) operating temperature; up to 95% relative humidity (non-condensing); up to 10,000 feet altitude; storage temperature -40° to +70° C.

Model	F2412	F2414	F2415
Connector	ST	ST	ST
Wavelength	Multimode 850nm	Multimode 1300nm	Single Mode 1300nm
Link Budget	26 + 1 dB	28 + 1 dB	30 + 1 dB
Maximum Range	3km / 1.86mi / 9,800ft	15km / 9.3mi / 49,000ft	30km / 18.6mi / 98,000ft
Fiber Optic Cable*	50/125, 62.5/125, 100/140	50/125, 62.5/125, 100/140	8/125, 9/125, 10/125

*Note: Multimode tests were performed on 62.5/125 µΜ fiber optic cable.
Single Mode tests were performed on 10/125 µΜ fiber optic cable.

SECTION 2

INSTALLATION

2.1 GENERAL

This section contains detailed information on the installation and initial checkout of the F2410 modems. Paragraph 2.2 contains general information on site selection and rack mounting. Paragraphs 2.3 through 2.6 contain detailed instructions for connecting the modems to your system and selecting the different options. Paragraph 2.7 contains initial checkout procedures.

2.2 SITE SELECTION AND MOUNTING

F2410 modems are designed to connect directly to the serial port (DB15F Connector) of PBX or multiplexer equipment with a cable (customer supplied). The circuit card is designed to be mounted in single or dual card standalone enclosures or in rack mounted 2-slot or 20-slot chassis. Table 1 lists available enclosures and chassis.

2.3 POWER REQUIREMENTS

F2410 modems operate from an AC power source or a DC power source with a DC voltage of +12 VDC, 1A. The power supplies used with modems when installed in a HF-1, HF-2, or HF-2SS are VERSITRON Model PSAC08 (US) or Model PSAC09 (European) providing 12 VDC, 1A. When installed in a HF-20, the AC150W Power Supply / System Monitor is used to supply power for all FOM II series circuit cards installed into the chassis. The AC150W requires two slots in the HF-20. For power redundancy, two AC150W units are required. Connect the power transformer to the F2410 unit before inserting its plug into an AC power source. No special tools are required. DC power may be used instead of an AC transformer, if available. This requires a 2.5mm socket with positive on the center and common on the concentric, and providing +12 VDC at 1A.

2.4 SWITCH SETTINGS

F2410 modems have one 8-position switch onboard the circuit card. This switch is located near the DB15 connector, as shown in Figure 2. The switch is labeled "SW3" on the circuit card, and is positioned such that the "ON" setting of each of the 8 switch positions is towards the front panel of the circuit card. The settings of the 8 switch positions are as specified in Tables 2 and 3.

Position 1 on the switch, RCODE, is used to set the protocol for the data received on the E1 link. Position 8, TCODE, likewise is used to set the protocol for the data transmitted on the E1 link. Both of these may be set for AMI or HDB3 protocols. These switches must be set properly prior to operation, and if the encoder or decoder settings do not agree with the input data, the unit may not function properly. Two loopback settings may be changed using switch positions 6 and 7. Position 6, RLOOP, allows for loopback of the copper interface, and Position 7, LLOOP, permits the loopback of the fiber interface. The local loopback is controlled from the front panel of the modem while in operation. Position 2 is not used. Positions 3-5 are set on the basis of the input impedance of the copper interface.

FIGURE 2. CIRCUIT DETAIL SHOWING SWITCH LOCATION

SWITCH 3	NAME	FUNCTION ON	FUNCTION OFF
POSITION 1	RCODE	AMI	HDB3
POSITION 2	NOT USED	N/A	N/A
POSITION 3	LEN 0	Input Impedance Settings: See Table 3.
POSITION 4	LEN 1
POSITION 5	LEN 2
POSITION 6	RLOOP	Remote Loop ON	Remote Loop OFF
POSITION 7	LLOOP	Local Loop ON	Local Loop OFF
POSITION 8	TCODE	AMI	HDB3

TABLE 2. SWITCH SETTINGS

2.4 SWITCH SETTINGS (Cont.)

Positions 3, 4 and 5 of the switch are set based on input impedance. As shown in Table 3, the modem may be configured to handle either 75Ω or 120Ω impedances. Two jumpers must also be set for the input impedance. Jumpers JP7 and JP8 must tie together pins 1 and 2 for 75Ω inputs and JP7 and JP8 must tie together pins 2 and 3 for 120Ω inputs.

There are eight jumpers on the circuit card. Except for JP7 and JP8 settings previously described, none of the other jumpers (JP1-JP6) should be changed from the positions set in the factory. They are used for test and diagnostic purposes only and are not to be reset by the user.

POSITION 3	POSITION 4	POSITION 5	APPLICATION
OFF	OFf	OFF	75Ω Coaxial
ON	OFF	OFF	120Ω Twisted Pair

TABLE 3. SWITCH SETTINGS VS. COPPER INTERFACE CABLE LENGTH

2.5 OUTPUT CONNECTIONS

F2410 modems use a standard 15-pin D sub miniature connector (female) for the electrical signal interface. Only four of the pins are used, however. Receive data is input on Pins 1 and 9 and transmit data is output on Pins 3 and 11.

2.6 LOOPBACK

F2410 modems have two loopback features. The first Loopback feature allows the user to test the fiber optic circuitry of the local unit, the fiber optic circuitry of the remote unit, the copper circuitry of the local unit, and the copper circuitry of the remote unit. The second Loopback feature loops the interface circuitry only.

2.6.1 Fiber/Copper Loopback

The fiber optic inputs and outputs of the F2410 modems are connected to a multiplexer. When the front panel loopback switch (LB) is switched ON, the multiplexer control bit is set high and fiber optic input data is looped to the output and back to the source. The copper signals entering through the interface circuitry are encoded and decoded by the multiplexer and likewise looped back to their source. If both the fiber and copper input and output signals match, then the optical and interface circuitry of both units is operating properly.

2.6.2 Interface Loopback

As listed in Table 2, RLOOP and LLOOP, switch positions 6 and 7, are used to loop the bipolar data signals at the interface. This allows for testing of the copper and fiber inputs and outputs between connected devices without going through the copper-to-fiber conversion circuitry.

2.7 INITIAL CHECKOUT PROCEDURE

F2410 modems contain no power on/off switch. Once the unit is properly installed and power is applied it is considered fully operational. The power indicator (PWR) should remain on as long as power is supplied to the unit. Upon initial power up, with no signal connections made, the PWR, alarm (ALM) and bipolar violation (BPV) LED indicators should be on. When signal connections are properly made, the transmit data (TXD) and receive data (RXD) LED indicators should be on and the ALM and BPV LEDs should go off.

Before beginning system operation the following items should be checked to verify proper installation:

1. Verify that the power plug is seated fully into the modem or seated firmly in the rack mount enclosure.

2. Verify that the fiber optic cable is crossed transmit to receive from unit one to unit two.

3. Verify that the ALM and BPV LEDs go out when the signals are applied to the modem.

4. Verify that the LOOP LED comes on and goes out with the LB switch on the front panel.

If a malfunction is detected during the initial checkout procedure, refer to Chapter 5 for information on isolating the malfunction in the unit.

SECTION 3

OPERATION

3.1 INTRODUCTION

This chapter contains a description of the operating controls and indicators associated with the F2410 modems. Since the modem is designed for continuous and uninterrupted operation, there are no operating requirements. Once the modem is powered up it should remain in service as long as required.

3.2 STATUS INDICATORS AND ALARM CIRCUITS

There are six LED indicators on the F2410 modem: power (PWR), alarm (ALM), transmit data (TXD), receive data (RXD), bipolar violation (BPV), and loopback (LOOP). No audible alarm is available. The F2410 modems contain a standard FOM II alarm circuit to monitor the optical connection and power supplies. The ALM LED is activated when no signal is present at the fiber optic interface. When AMI signals are decoded, bipolar violation circuitry checks the signal. The BPV LED is activated when a violation is detected and it remains on until turned off by the RESET switch on the front panel near that LED.

3.3 Operating Controls

The only operating controls associated with the F2410 are two front panel switches. The LB switch is used to enable the loopback capability of the circuit. This is described in Section 2.6 and is normally only used for diagnostic purposes when initializing or reconfiguring the system using the F2410 modem. The reset push-button switch is only used if a bipolar violation occurs. The switch settings onboard the circuit card are described in Tables 2 and 3 in Section 2.4 and are set prior to first using the modem. Further changes are not required unless the system requirements change.

SECTION 4

THEORY OF OPERATION

4.1 INTRODUCTION

F2410 modems provide a transparent, synchronous path for E1-standard signals. By converting to fiber optic signaling, a distance of 3km (1.86mi/9,800ft) for 850nm multimode LEDs, 15km (9.3mi/ 49,000ft) for 1300nm multimode LEDs, or 30km (18.6mi/98,000ft) for 1300nm single mode LEDs may be traversed without the need for a repeater or amplifier. In addition, the use of fiber optic cable as the transmission medium provides EMI/RFI protection and data security.

In the F2410 transmitter circuitry, the data is received via Pins 1 and 9 of the DB15 connector. The signal is decoded for AMI or HDB3 protocol, then Manchester encoded (which embeds a clock signal) with a Field Programmable Gate Array (FPGA). Next the signal is converted into an optical signal. The optical signal transmitter then sends the signal out onto the fiber optic cable.

Through the receiver circuitry of the F2410 the same process occurs in reverse. First the optical signal is received and converted back to an electrical signal. The FPGA decodes the Manchester data and clock signals. The data signal is then encoded for the AMI or HDB3 protocol and output to Pins 3 and 11 of the DB15 electrical signal interface. To the multiplexer or PBX terminal equipment connected to the F2410 pair, the transition from copper to fiber and back is transparent.

SECTION 5

MAINTENANCE AND TROUBLESHOOTING

5.1 INTRODUCTION

This chapter contains general information designed to isolate a malfunction in the F2410 to a replaceable unit. These units are not equipped with redundancy. Therefore, a failure in one of these units would interrupt service.

5.2 FAULT ISOLATION

The steps in Table 4 should be taken to check a non-operating modem. Contact VERSITRON Customer Service for additional diagnostic assistance or to arrange for repair as necessary.

STATUS INDICATOR	PROBABLE CAUSE	CORRECTIVE ACTION
POWER (PWR) LED is off.	No AC power.	Check that both ends of the Transformer are connected.
	Blown Fuse	Replace with 800 mA, 5 x 20 mm Slo-Blo fuse.
	Other power supply circuit problem.	Contact VERSITRON Customer Service for assistance.
ALARM (ALM) LED is on.	Incorrect optical signal level received at receiver input.	1. Check that fiber optic cable is properly connected to RX connector.
		2. Check that the remote unit power is on and the RX fiber on one end is connected to the TX fiber on the other end.
		3. Measure the optical levels on both ends (if possible) in order to check the optical link.
		4. Contact VERSITRON Customer Service for assistance.
DATA (TXD, RXD) LEDs are off or not responding as expected.	Switches in wrong position.	Check that the switch is set for the correct electrical interface protocol.
	No input on the electrical interface connector.	Check that the interface connector is connected securely.
BPV LED continuously on.	Switches in wrong position.	Check that the switch is set for the correct AMI or HDB3 protocol.
	Inverted input on the electrical interface connector.	Check that the interface connector is wired correctly.

F2410

FOM II Series

Fiber Optic Modem

Technical Manual

E1

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