Fibre Channel electrical interface explained

The Fibre Channel electrical interface is one of two related Fibre Channel standards that can be used to physically interconnect computer devices. The other standard is a Fibre Channel optical interface, which is not covered in this article.

Fibre Channel signal characteristics

Fibre channel electrical signals are sent over a duplex differential interface. This usually consists of twisted-pair cables with a nominal impedance of 75 ohms (single-ended) or 150 ohms (differential). This is a genuine differential signalling system so no ground reference is carried through the cable, except for the shield. Signalling is AC-coupled, with the series capacitors located at the transmitter end of the link.

The definition of the Fibre Channel signalling voltage is complex. Eye-diagrams are defined for both the transmitter and receiver. There are many eye-diagram parameters which must all be met to be compliant with the standard. In simple terms, the transmitter circuit must output a signal with a minimum of 600 mV peak-to-peak differential, maximum 2000 mV peak-to-peak differential. A good signal looks rather like a sine-wave with a fundamental frequency of half the data rate, so 1 GHz for a typical system running at 2 gigabits per second.

The Bit-Error Rate (BER) objective for Fibre Channel systems is 1 in 1012 (1 bit in 1,000,000,000,000 bits). At 2 Gbit/s this equates to seven errors per hour. Therefore, this is a common event and the receiver circuitry must contain error-handling logic. In order to achieve such a low error-rate, jitter "budgets" are defined for the transmitter and cables.

Fibre Channel connector pinouts

There are various Fibre Channel connectors in use in the computer industry. Details of their pinouts are distributed between different official documents. The following sections describe the most common Fibre Channel pinouts with some comments about the purpose of their electrical signals.

The most familiar Fibre Channel connectors are cable connectors, used for interconnects between initiators and targets (usually disk enclosures). There are also "device connectors" that can be found on Fibre Channel disk-drives and backplanes of enclosures. The device connectors include pins for power and for setting disk options.

9-pin "DE-9" cable connector

Pin Signal name Comments
1+OUTFibre channel output
2+5VOptional
3Module Fault DetectOptional
4Reserved
5+INFibre channel input
6-OUTFibre channel output
7Output DisableOptional
8GNDOptional, return for pin 2
9-INFibre channel input

Optional pins 2, 3, 7, and 8 are intended for use with an external optical converter. This is often called a Media Interface Assembly (MIA).

Fibre channel DE-9 connectors often have only the 4 required contacts installed. Note that they are the four outermost contacts i.e. the same as used for Token Ring, this is an easy way to tell a fibre channel cable from an RS-232 cable.

8-pin "HSSDC" cable connector (High Speed Serial Data Connection)

Pin Signal name Comments
1+OUTFibre channel output
2GNDOptional, return for pin 7
3-OUTFibre channel output
4Module Fault DetectOptional
5Output DisableOptional
6-INFibre channel input
7+5VOptional
8+INFibre channel input

Optional pins 2, 4, 5, and 7 are intended for use with an external optical converter. This is often called a Media Interface Assembly (MIA).

7-pin "HSSDC2" cable connector (High Speed Serial Data Connection)

Pin Signal name Comments
1GND
2-OUTFibre channel output
3+OUTFibre channel output
4GND
5+INFibre channel input
6-INFibre channel input
7GND

40-pin "SCA-2" disk connector

Although SCA-2 is the official name for this connector, it is often called SCA-40 to distinguish it by its pin count from other similar connectors.

Pin Signal name Comments
1-EN Bypass Port 1Output driven high when port 1 is operating correctly
2+12V
3+12V
4+12V
5-Parallel ESIInput to allow ESI operation using the SELx pins
6-Drive Present
7ACTLEDOutput to drive the activity LED cathode
8Power Control
9START1Input to control spin-up behavior (see the Disk options section)
10START2Input to control spin-up behavior (see the Disk options section)
11-EN Bypass Port 2Output driven high when port 2 is operating correctly
12SEL6Device ID bit 6 / ESI write clock
13SEL5Device ID bit 5 / ESI read clock
14SEL4Device ID bit 4 / ESI acknowledge clock
15SEL3Device ID bit 3 / ESI bit 3
16FLTLEDOutput to drive the fault LED cathode
17DEVCTRL2Input to control interface speed (see the Disk options section)
18DEVCTRL1Input to control interface speed (see the Disk options section)
19+5V
20+5V
21+12V Charge
22GND (12V)
23GND (12V)
24+IN1Fibre channel input
25-IN1Fibre channel input
26GND (12V)
27+IN2Fibre channel input
28-IN2Fibre channel input
29GND (12V)
30+OUT1Fibre channel output
31-OUT1Fibre channel output
32GND (5V)
33+OUT2Fibre channel output
34-OUT2Fibre channel output
35GND (5V)
36SEL2Device ID bit 2 / ESI bit 2
37SEL1Device ID bit 1 / ESI bit 1
38SEL0Device ID bit 0 / ESI bit 0
39DEVCTRL0Input to control interface speed (see the Disk options section)
40+5V CHARGE

Disk options

Some of the input signals to a Fibre Channel disk are used to control options, as follows:

START options - if all the disks in an enclosure spin-up immediately on power-on, this can overload the power-supply. Two methods are available to avoid that problem:

START1 START2 Spin-up behaviour
00Automatic, immediate
01Wait for Start Unit SCSI command
10Staggered, delayed depending on loop address
11Reserved

DEVCTRL options - a disk that has the wrong interface speed can cause serious problems if it is inserted into an enclosure. That problem is avoided by providing three input pins to the disk that define the interface speed at which it will operate:

DEVCTRLx value Interface speed
0-4Reserved
54 GB/s
62 GB/s
71 GB/s

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