Difference between revisions of "Intensify Nx50 setup guide"

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In case of any questions, please don't hesitate to [[Granite Devices support|contact us]].
 
In case of any questions, please don't hesitate to [[Granite Devices support|contact us]].
  
{{info|Pre-production version of Nx50 setup guide can be found [http://granitedevices.com/w/index.php?title=Intensify_Nx50_setup_guide&stableid=1748 here]. Please note that some I/O signal characteristics and pin out has changed.}}
+
{{info|Pre-production version of Nx50 setup guide can be found [[http://granitedevices.com/w/index.php?title=Intensify_Nx50_setup_guide&stableid=1748 here]]. Please note that some I/O signal characteristics and pin out has changed.}}
 
==Physical installation and cooling==
 
==Physical installation and cooling==
 
Nx50 should be mounted inside an enclosure by using spacer feet attached to the four corner holes.
 
Nx50 should be mounted inside an enclosure by using spacer feet attached to the four corner holes.

Revision as of 00:07, 10 June 2014

Intensify Nx50 PCB from top side

This is the intallation & user guide for the Intensify Nx50 laser diode driver. Read it through before operating the device.

In case of any questions, please don't hesitate to contact us.

Physical installation and cooling

Nx50 should be mounted inside an enclosure by using spacer feet attached to the four corner holes.

Nx50 (single board) efficiency vs load current at various laser diode forward voltages

Nx50 has low power losses due to highly efficient multiphase switching converter technology. Power loss can be calculated by using the offered efficiency data as setpont.

In most cases Nx50 is sufficiently cooled with natural convection. This is best achieved by mounting boards vertically and leaving at least 25 mm free air space around both sides.

However, if natural convection does not offer sufficient cooling (i.e. if peak surface temperature is near or exceeds 100°C), then forced convection is necessary. This can be achieved by placing a fan or blower on the side of PCB so that air flow passes along board surface.

Wiring

J1 connector

J1 connector is the user side I/O of the driver. This connector contains the control and feedback signals. All signal lines of the port are ESD protected by dedicated suppressors.

Mating connector type is a 10 pin flat ribbon cable connector with 0.1"/2.54 mm pin pitch and a polarity key. See spec sheet of compatible connector here.

J1 pin out

10 Pin IDC connector pinout
Pin # Signal name Direction Signal description Impedance vs GND
1 PULSE In Pulse control:
  • When LOW or open, output current is 100% of ISET
  • When HIGH, output current is 3.5% of ISET
10 kOhm
2 GND I/O and Analog ground 0 Ohm
3 IMON Out Current monitor 0-10 V analog output 1 kOhm
4 GND I/O and Analog ground 0 Ohm
5 VMON Out Voltage monitor 1:1 analog output 1 kOhm
6 GND Out I/O and Analog ground 0 Ohm
7 ISET+ In Current setpoint 0-10 V positive input (differential) 51 kOhm
8 ISET- In Current setpoint 0-10 V negateive input (differential) 51 kOhm
9 ENABLE In LDD enable:
  • When HIGH, LDD output enabled
  • When LOW or open circuit, LDD output disabled
6.6 kOhm
10 GND I/O and Analog ground 0 Ohm

Impedances

When driving an J1 input pin, the source impedance of controller should be significantly lower than input impedance of the corresponding pin. I.e. if input impedance is 51 kOhm, then recommended source impedance is less than 5 kOhm max, preferrably 0.5 kOhm. Lower source impedance yields lower voltage drop error.

Also when an output of J1 is connected to the input of controller, the controller input impedance should be significantly higher than J1 pin impedance. I.e. when connecting VMON (1 kOhm) to analog input or ADC, the controller input impedance should be at least 10 kOhm. However all outputs are short circuit proof and input impedance recommendation affects only monitor accuracy.

See impedance column of pin out table

Digital signals

All digital signals (PULSE & ENABLE) are referenced to GND and applicable voltage levels are:

State Voltage range
Logic LOW -0.3 .. 0.6V
Logic HIGH 3.0 - 26 V

Analog signals

Analog input signal support differential signaling to cancel noise and ground loop induced error. These are designed to be compatible with another differential source as well as single ended systems. The differential signals allow up to +/- 1.5V difference on ground reference potentials between Nx50 and controller without losing accuracy.

Connection to differential 0-10V analog I/O:

Controller J1 signal
Analog in 1 + IMON
Analog in 1 - GND
Analog in 2 + VMON
Analog in 2 - GND
Analog out 1 + ISET+
Analog out 1 - ISET-
Ground GND

Connecting to single ended 0-10V analog I/O. Assuming that I/O is referenced to Ground.

Controller J1 signal
Analog in 1 IMON
Analog in 2 VMON
Analog out 1 ISET+
Ground ISET-
Ground GND

Power

A regulated 12VDC power supply should be connected to hole terminals labeled GND and +12V. Required power is nearly directly proportional to output power plus losses.

For example outputting 40A to 2.0V diode equals output power of 80W. With losses the needed power is about 85-90W which equals 7.0-7.5A @ 12V.

Laser diode

Laser diode is connected to hole terminals labeled O+ and O-. O+ goes to LD anode and 0- to cathode.

Connecting parallel

Three Nx50 drives connected parallel by stacking with hex standoffs and ribbon cable with three IDC connectors

Nx50 boards may be connected parallel to increase output current range simply by connecting all power and I/O lines parallel pin-by-pin basis.

This can be achieved by stacking them by using metallic standoffs to form conductive path between O+, O-, GND, and +12V terminals. Use M4 or M5 threaded standoffs with minimum height of 16 mm.

J1 connector may be paralleled by inserting multiple 10 pin IDC connectors to the single ribbon cable. By this method all J1 pins are properly connected parallel pin-to-pin basis.

Usage

The device starts operating instantly after powered and and proper signals fed to J1 pins. No other initialization is needed.

CW usage

Mandatory connections
  • LD connected between O+/O-
  • 12VDC supply connecter between +12V/GND
  • J1 connector pins:
    • GND connected to controller's ground reference:
    • 0-10V current setpoint signal fed to ISET+/ISET-
    • ENABLE set to HIGH or tied to GND
Optional J1 connections
  • IMON wired to analog input
  • VMON wired to analog input
  • PULSE set to HIGH or left open

Pulsed usage

LD current rise from 2.5A to 50A when PULSE set to LOW
LD current fall from 50A to 2.5A when PULSE set to HIGH. Current typically dips to 0A temporarily.

For pulsed usage it is recommended to use PULSE input or modulate the ISET analog voltage. It is not recommended to set current to 0 during off-periods for to achieve faster pulse rise times and zero overshoot. Recommended bias current during off-periods is 2-10% of current setpoint.

Mandatory connections
  • LD connected between O+/O-
  • 12VDC supply connecter between +12V/GND
  • J1 connector pins:
    • GND connected to controller's ground reference:
    • 0-10V current setpoint signal fed to ISET+/ISET-
    • ENABLE set to HIGH or tied to GNDA
    • PULSE set pulse source. Logic LOW means 100% of set current and HIGH reduces output current to 3.5% (bias current to allow faster rise time)
Optional J1 connections
  • IMON wired to analog input
  • VMON wired to analog input