This section describes all types of input and output signals available with Corsight cameras, including their characteristics and when necessary including connection examples. Location and pinouts of the connectors carrying the signals are documented in Mechanic and Connector and cable description.
Power supply
DC power input
CORSIGHT cameras are designed for a power supply input range of 24 V ±10%. The power consumption strongly depends on the connected peripherals — devices being powered by CORSIGHT through the USB or other interfaces. The power consumption of the CORSIGHT itself is typically 15 W, while the total power consumption, including the connected peripherals, should not exceed 25 W. A suitable power supply for CORSIGHT is available from NET.
The customers designing an own power supply will find the information about the power input connector in Section “I/O connector”.
Power over Ethernet (PoE+)
The CORSIGHT cameras can be also powered using the Power over Ethernet option. The cameras are compatible with the Power over Ethernet standard, versions IEEE 802.3af and 802.3at. They should be used with PoE switches (“endspans”) or power injectors (“midspans”) complying with the IEEE 802.3af/IEEE 802.3at specifications.
Both PoE modes (A and B) are supported by the camera. Beware of using the PoE cameras with 100Mbit Ethernet only cables, where the “spare” wire pairs might be omitted. With such cable, the power wouldn't be delivered when using Mode B compatible power sourcing equipment.
The CORSIGHT camera models are classified in the power level class 4. The power consumption with PoE is slightly higher than consumption with a “regular” power supply. When connecting multiple CORSIGHT cameras to a single PoE switch, verify how much total power the switch can provide and how it handles cases when the limit is exceeded.
Both PoE modes (A and B) are supported by the camera.
Beware of using PoE cameras with 100Mbit Ethernet cables, where the “spare” wire pairs might be omitted. With such cable, the power wouldn't be delivered when using Mode B compatible power sourcing equipment.
Connector and cable description
| All the grounds from individual connectors are connected inside the camera. |
I/O Connector and Pinout
17-pin male M12 connector for digital i/o (optocoupler and TTL inputs/outputs) and power input.
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An adapter cable is available (see Section “Accessories”), with D-sub 25-pin female interface connector. The table below lists the pinouts also for the connectors of the adapter cable.
I/O connector, pinout (including pin numbers on the D-sub-25 adapter cable)
Pin # | Signal | D-Sub 25 |
|---|---|---|
1 | Power In- | 12 |
2 | Power In+ | 19 |
3 | Optocoupler Input 3 Anode | 7 |
4 | Ground | 5 |
5 | Optocoupler Output 1-3 Collector | 10 |
6 | Optocoupler Output 0 Emitter | 9 |
7 | Optocoupler Output 1 Emitter | 11 |
8 | Optocoupler Output 3 Emitter | 24 |
9 | TTL Input | 21 |
10 | TTL Output | 20 |
11 | Optocoupler Input 2 Anode | 6 |
12 | Optocoupler Input 0 Cathode | 2 |
13 | Optocoupler Input 0 Anode | 1 |
14 | Optocoupler Output 0 Collector | 8 |
15 | Optocoupler Output 2 Emitter | 25 |
16 | Optocoupler 1 Input Anode | 3 |
17 | Optocoupler 1-3 Input Cathode | 4 |
Pins 13, 14, 15, 16, 17, 18, 22, 23 on the D-sub 25 connector are not connected.
PC system connector
24-pin female M16 connector for DP++, RS232 and USB 2.0.
An adapter cable are available (see Section “Accessories”), separating individual signal groups into three dedicated connectors: DP++ male, USB Type A female, and RS232 (D-sub 9-pin male). The table below lists the pinouts also for the connectors of the adapter cable.
CORSIGHT PC system adapter cable, DP++ connector
CORSIGHT PC system adapter cable, USB connector
CORSIGHT PC system adapter cable, D-sub 9-pin connectors (RS-232)
PC system connector, pinout (including pin numbers on the DP++/USB/RS232 adapter cable)
M16 | Signal | DP | USB | RS-232 |
|---|---|---|---|---|
1 | ML0+ | 12 | - | - |
2 | ML3- | 1 | - | - |
3 | ML2+ | 6 | - | - |
4 | ML2- | 4 | - | - |
5 | ML3+ | 3 | - | - |
6 | ML0- | 10 | - | - |
7 | ML1+ | 9 | - | - |
8 | ML1- | 7 | - | - |
9 | AUX- | 17 | - | - |
10 | GND | 2, 5, 8, 11, 16 | - | - |
11 | Hot Plug | 18 | - | - |
12 | +5V | - | - | - |
13 | +5V | - | - | - |
14 | GND | - | 4 | - |
15 | GND | - | - | - |
16 | AUX+ | 15 | - | - |
17 | USB- | - | 2 | - |
18 | +5V USB | - | 1 | - |
19 | GND | - | - | 5 |
20 | RS232_TX | - | - | 3 |
21 | CONF1 | 13 | - | - |
22 | RS232_RX | - | - | 2 |
23 | +5V USB | - | - | - |
24 | USB+ | - | 3 | - |
- | Shield | - | - | - |
Pins 14, 19, 20 on the DP connector are not connected.
Pins 1, 4, 6, 7, 8, 9 on the RS232 D-sub 9 connector are not connected.
The cable carries following signals via twisted pair wires: ML0+/ML01, ML1+/ML1-, ML2+/ML2-, ML3+/ML3-, AUX+/AUX-, USB-/USB+.
All grounds are connected together.
Ethernet connector
8-pin female M12 Ethernet connector.
An adapter cable is available (see Section “Accessories”), with standard Ethernet connector, 8P8C modular plug, often also referred to as RJ-45.
CORSIGHT Ethernet connector, pinout
Pin | Signal (1000BASE-T) | Signal (10BASE-T, 100BASE_TX) | Pin RJ-45 |
1 | BI_DC- | NC | 5 |
2 | BI_DD+ | NC | 7 |
3 | BI_DD- | NC | 8 |
4 | BI_DA- | TX- | 2 |
5 | BI_DB+ | RX+ | 3 |
6 | BI_DA+ | TX+ | 1 |
7 | BI_DC+ | NC | 4 |
8 | BI_DB- | RX- | 6 |
Status LED
The CORSIGHT cameras are equipped with a set of status LED's. The positions of the LED's on camera's side is shown on the figure below. The purpose of the individual LED's (starting from connector side) is:
WLAN activity (blue)
User LED (green, software programmable)
Ethernet speed (green, still for 1GB, blinking for 100Mb Ethernet)
Ethernet link (orange)
Power (green)
SATA activity (orange)
Optocoupler interface / Strobe Interface
Optically isolated inputs and outputs.
Optocoupler basics
 Diagram of basic optocoupler function | An optocoupler is a device using optical path to transfer an electronic signal between two circuits. It basically consists of a photodiode converting the input signal to light and a phototransistor converting the light again to electronic signal. The optocoupler is useful in situations where one part of the circuit needs to be galvanically isolated from the other part to prevent damage or unwanted interference. It is used to prevent ground loops or to block voltage spikes. For effective use of the optocoupler it is important to control it using an independent power supply. When the external circuit is galvanically connected to the camera (eg. when reusing the camera's power to control the optocoupler), the optocoupler's protective function is eliminated. |
Optocoupler parameters summary
Parameter | Input Value | Output Value |
|---|---|---|
Operating voltage | 5 - 24 V | 5 - 24 V |
Input current | 7.5 mA | < 100mA |
External resistor requirement | No | Yes, output current must be limited to 100 mA |
ON voltage level | > 4.5 V | |
OFF voltage level | < 1.5 V | |
OFF to ON delay | < 125 ns | 750 ns |
OFF to ON rise time (10 to 90%) | 1.0-4.0 µs | |
ON to OFF delay | < 125 ns | 2.4 – 25 µs |
ON to OFF fall time (90 to 10%) | 9.0 – 140 µs | |
OFF to ON jitter | ± 5 ns | ± 20 ns |
ON to OFF jitter | ± 5 ns | ± 0.1 µs |
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Optocoupler inputs
The CORSIGHT camera is equipped with four optically isolated input lines. One input optocoupler is fully independent, the other three are connected with a common cathode (Section “I/O connector”) due to limited number of pins on the I/O connector.
The optocoupler input's logical state is understood as logical 0 if no current is flowing through the optocoupler diode, logical 1 if current is flowing through the diode.
The optocoupler is guaranteed to be switched on (logical 1 status) when the voltage applied to the input is in range of 5 - 24V (tolerance 10%). It is guaranteed to be switched off (logical 0 status) when the applied voltage is under 1.5V. The input status is undefined between 1.5V and 4.5V, the input voltage must not exceed the 24V limit!
The optocoupler inputs have no protection against wrong polarity. Be sure to connect them always with correct polarity according to the documented wiring diagrams and connector pinouts.
The nominal input current is 7.5 mA — the input signal must be able to deliver at least this amount of current.
The optocoupler inputs are TTL compatible provided that the signal source is capable of supplying the input current of 7.5 mA.
The optocoupler input lines are equipped with a debouncer to prevent generating unwanted input signals.
The input lines are using fast optocouplers: The propagation time is under 125 ns, for both rising and falling signal edge (assuming input signal with strongly steep edge). The exact switching speed may vary with temperature and the used input voltage level - the listed specifications are the worst case values.
Optocoupler outputs
The CORSIGHT camera is equipped with four optically isolated output lines. One output optocoupler is fully independent, the other three are connected with a common collector (Section “I/O connector”) due to limited number of pins on the I/O connector.
After power up, the optocoupler outputs are in high impedance state and they remain in that state until reconfigured from the software interface. Whenever the optocoupler output is disconnected in the SW interface, it gets in high impedance status.
The optocoupler output's logical state is understood as logical 0 when its output transistor is in high impedance, logical 1 if it is in low impedance mode.
The optocoupler output work with operating voltage range of 5-24 V. The maximal switched output current is 100 mA per optocoupler, higher current could damage the optocoupler output circuit.
The rising edge (switching to logical 1) propagation time is 750 ns, the falling edge propagation time is under 25 µs. The exact switching speed may vary with temperature and the used input voltage level — the listed specifications are the worst case values.
TTL I/O's
Standard 5V TTL (transistor-transistor logic) interface.
After power up, the TTL outputs are driven low — and they remain driven low until reconfigured from the software interface. Whenever the TTL output is disconnected in the SW interface, it gets in driven low status. TTL inputs are pulled up to 5V inside the camera to guarantee a stable input in case nothing is connected. To generate a steep edge the TTL input driver should be capable of driving and sinking 10mA.
The TTL input's and output's logical state is understood as logical 1 when it's driven high (5V) and logical 0 when it's not driven (0V).
The TTL input lines are equipped with a debouncer to prevent generating unwanted input signals.
The delays listed in the table are setup dependent mean values, while the jitters are maximal deviations (± ) from those mean values.
TTL input/output parameters summary
Parameter | Value |
Operating voltage ON voltage level | 5V±10% (absolute maximum 6.5V) > 3.5 V |
OFF voltage level | < 1.5 V |
High level output current | -32mA max / high level at 3.8V min |
Low level output current | 32mA max / low level at 0.55V max |
Input to sensor trigger delay | 19 µs (jitter +13/-2 µs) |
TTL-in to TTL-out delay | 32 µs (jitter +10/-2 µs) |
Serial port interface
Standard RS232 communication interface, accessible directly from the camera's feature tree.
Configurable communication parameters are: baud rate, parity, data bits, stop bits.
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