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High-Speed, Fiber-Optic Reference Transmitters


  • Digital Reference Transmitters for 12.5 or 40 Gb/s Bit Rates
  • Linear Reference Transmitters with 35 GHz Analog Bandwidth
  • Integrated RF Amplifier and Modulator with Bias Control
  • Integrated C-Band Tunable, L-Band Tunable, or 1310 nm Laser

MX40B

40 Gb/s Digital Reference Transmitter
Internal C-Band Tunable Laser

MX35E-LB

35 GHz Linear Reference Transmitter
Internal L-Band Tunable Laser

32 Gb/s Eye Diagram from the MX35E

Related Items


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Reference Transmitter Block Diagram
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Block diagram showing the internal setup of the high-speed reference transmitters.

Janis Valdmanis, Ph.D. Optics
Ultrafast Optoelectronics
General Manager

We Design, Develop, and Manufacture
Equipment up to 70 GHz

Questions?

Demo Unit Requests?

Product Suggestions?

Custom or OEM Applications?

Contact Me

Features

  • All Reference Transmitters Include:
    • Mach-Zehnder Intensity Modulator
    • Bias Controller with Manual and Fully Automatic Operation Modes
    • RF Amplifier
    • Integrated C-Band Tunable, L-Band Tunable, or 1310 nm Fixed-Wavelength Laser (Contact Tech Support for an 850 nm Fixed-Wavelength Laser)
    • Variable Optical Attenuator (VOA) for Automatic or Manual Power Control
  • Digital Reference Transmitters
    • MX10B Series for Applications up to 12.5 Gb/s
    • MX40B Series for Applications up to 40 Gb/s
    • User-Adjustable RF Amplifier Output Swing
  • Linear Reference Transmitters
    • 35 GHz Analog Bandwidth
    • User-Adjustable RF Ampllifier Gain 
  • Operation from 1250 to 1610 nm Using External Laser Source
  • External Loop-Back Cables Support Custom Configurations
  • Control via Intuitive Touchscreen Interface or Remotely Using USB or RS-232 Connections
  • Custom Configurations Available by Contacting the Ultrafast Optoelectronics Team

Thorlabs' Reference Transmitters are designed for high-speed fiber optic test and measurement applications. They are fully-integrated and user-configurable solutions based on proven lithium niobate (LiNbO3) modulator technology driven by high-fidelity RF amplifiers. The MX10B and MX40B series are designed for digital applications, and the maximum output swing of their limiting RF amplifiers is user-adjustable (for more information, see the Operation tab). The MX35E series is designed for linear applications, and the gain of its linear RF amplifier is user-adjustable. Each reference transmitter has a built-in telecom-grade laser and fully-featured modulator bias control. Variable optical attenuators (VOAs) and power monitors enable completely automatic output power control and stabilization. These instruments are ideal for use in either an R&D laboratory or in a manufacturing environment for creating optical links, performing experiments requiring fast optical modulation, or testing other components.

The internal C- and L-band lasers are tunable over a range of 1527.6 nm - 1565.5 nm (191.50 THz - 196.25 THz) and 1570.0-1608.8 nm (186.35 THz - 190.95 THz), respectively, on the ITU 50 GHz grid. A dither feature for wavelength stabilization is available in both tunable internal laser options (see the Operation tab for more information). The internal 1310 nm fixed-wavelength laser of the MX10B-1310, MX40B-1310, and MX35E-1310 has a typical wavelength of 1310 nm. Reference transmitters with an integrated 850 nm fixed-wavelength laser are also available upon request (contact Tech Support). An external laser source, operating from 1250 to 1610 nm, can also be used to provide the optical input.

The laser input port uses PM fiber with light linearly polarized along the slow axis (aligned to the connector key) and can accept a maximum input power of 20 dBm (100 mW). Each fiber bulkhead accepts FC/PC connectors. For complete specifications, please see the Specs tab. The MX10B series also includes an external loop-back cable for the driver RF output and modulator RF input ports, which provides the opportunity to use an external driver, if desired (see the Front & Back Panel tab for details). The amplifier RF port on the MX10B series accepts SMA connectors, while the amplifier RF port on the MX40B and MX35E series accepts 2.92 mm (K™)† connectors. Please see Thorlabs' complete selection of microwave cables and adapters.

These reference transmitters can be controlled in two ways. The simplest method is using the intuitive touchscreen interface, which gives the user complete control over all instrument functionality. These instruments can also be operated remotely via the RS-232 or USB ports on the back panel. The Operation tab describes the graphical user interface (GUI) and user-customizable features, and we provide a remote control user guide and a remote control software tool (see the Software tab) for download.  

Thorlabs also offers Optical Transmitters based on phase modulators. Please see the Selection Guide tab above for all of our transmitter instruments.

K™ is a trademark of Anritsu.

Digital Reference Transmitters (MX10B and MX40B Series)

Digital Reference Transmitter Eye Diagram
Click to Enlarge

10 Gb/s Eye Diagram from MX10B Series

Digital Reference Transmitter Eye Diagram
Click to Enlarge

15 Gb/s Eye Diagram from MX10B Series

Both the MX10B and MX40B series of transmitters are based on the use of high-gain, limiting amplifiers with user adjustable output voltage swing. Because of their high gain, they can accommodate a wide range of input voltages, as is shown in the plot below. In these devices, the gain is always held constant and only the output voltage swing applied to the modulator is adjustable. This allows the user to control the optical extinction ratio of the signal from the modulator. Both models also offer user-adjustable eye-crossing points, which enable fine control of the eye transitions.

The MX10B series can operate up to 12.5 Gb/s and includes an external loop-back cable for connecting the RF output to the modulator input. This feature allows the user to use an external modulator driver, if desired (see the Front & Back Panel tab for details). The MX40B series supports bit rates up to 40Gb/s but has a direct internal connection from the amplifier to the modulator. Both digital transmitters are well suited to many binary modulation formats, including RZ, NRZ, and OOK.

Digital Reference Transmitter Eye Diagram
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20 Gb/s Eye Diagram from MX40B Series

Digital Reference Transmitter Eye Diagram
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40 Gb/s Eye Diagram from MX40B Series
Linear Reference Transmitter Eye Diagram
Click to Enlarge

Limiting amplifiers in the MX10B and MX40B series provide high gain and a user-adjustable output swing in 0.1 V increments. 

Linear Reference Transmitters (MX35E Series)

The MX35E series of transmitters is based on the use of an RF amplifier that provides a linear relationship between the input and output voltages (see plot below). Adjusting the amplifier's gain changes the slope of output vs. input voltage curves.

Linear Reference Transmitter PAM4 Multi-Level Eye Diagram
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25 GBaud/s PAM4 Eye Diagram from MX35E Series

Linear Reference Transmitter Eye Diagram
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20 Gb/s Binary Eye Diagram from MX35E Series

Linear Reference Transmitter Eye Diagram
Click to Enlarge

40 Gb/s Binary Eye Diagram from MX35E Series

The adjustable gain control allows the output of the amplifier to remain linear across a broad range of input signal levels. Note, however, that the linear range of the whole system is still limited by the non-linear response of the lithium niobate (LiNbO3) modulator. As a result, large RF output signals will experience some compression, which can actually be an advantage in some applications.

The MX35E series is designed for linear applications that require frequency response up to 35 GHz, which makes them compatible with high bit-rate modulation schemes that rely on multi-level encoding, such as PAM4.

Linear Reference Transmitter Eye Diagram
Click to Enlarge

Linear amplifiers provide a linear relationship between voltage input and output. Different line slopes indicate different gain settings in the MX35E series. Gain is user-adjustable in 1 dB increments.

General System Specifications
Item # MX10B MX10B-LB MX10B-1310 MX40B MX40B-LB MX40B-1310 MX35E MX35E-LB MX35E-1310
Amplifier Type Digital (Limiting) Linear (Analog)
Bit Rate/Frequency (Max) 12.5 Gb/s 40 Gb/s 35 GHz
Internal
Laser
Laser Type C-Band
Tunable
L-Band
Tunable
1310 nm Fixed-
Wavelength
C-Band
Tunable
L-Band
Tunable
1310 Fixed-
Wavelength
C-Band
Tunable
L-Band
Tunable
1310 nm Fixed-
Wavelength
Wavelength Rangea 1527.6 -
1565.5 nm
1570.0 -
1608.8 nm
1310 nm (Typ.) 1527.6 -
1565.5 nm
1570.0 -
1608.8 nm
1310 nm (Typ.) 1527.6 -
1565.5 nm
1570.0 -
1608.8 nm
1310 nm (Typical)
Output Power (Typ.) 13.5 dBm
External
Laserb
Wavelength Rangec 1250 nm - 1610 nm
Optical Input Power 20 dBm (Max); 22 dBm (Absolute Max)
Power Calibration Points 1310 nm, 1550 nm, and 1590 nm
Optical Extinction Ratio 13 dB (at 12.5 Gb/s) 13 dB (at 40 Gb/s) 13 dB (at 32 Gb/s)
Electrical Return Lossd -10 dB (Any RF Port, Typical)
Modulator Type Intensity
Optical Insertion Loss (Typ.)e 5 dB (1550 nm); 7 dB (1310 nm)
Internal Optical Fiber PM Ports: PM PANDA Fiber
SM Port: SMF-28-Compatible Fiber
Fiber Connectors FC/PC, 2.0 mm Narrow Key
  • The C-Band and L-Band lasers are tunable in 50 GHz steps. An 850 nm fixed-wavelength laser can be substituted upon request: contact Thorlabs’ Tech Support.
  • User-Supplied
  • Using the modulator at another wavelength (e.g. visible light) may cause an increase in insertion loss and will void the warranty.
  • To the -3 dB Bandwidth
  • Laser IN to Optical OUT.
Intensity Modulator Specifications
Item # Prefix MX10B MX40B MX35E
Electro-optic Bandwidth (-3 dB) 14 GHz 35 GHz 35 GHz
DC Optical Extinction Ratio (On/Off) 20 dB
RF Drive Voltage (Vpi)a 5.5 V
Modulator RF Inputb,c 5.5 V (Typical)
7 V (Max)
10 V (Absolute Max)
N/A N/A
Insertion Loss 4 dB (1550 nm), 6 dB (1310 nm)
  • Peak to Peak Voltage at 1 GHz
  • Peak to Peak Voltage
  • This specification is quoted only for the MX10B, as it has a loop-back between the Amplifier RF OUT and Amplifier RF IN ports. The modulator RF input is not accessible on the MX40B and MX35E.
Digital (Limiting) RF Amplifier Specifications
Item # Prefix MX10B MX40B
Bit Rate (Maximum) 12.5 Gb/s 40 Gb/s
Amplifier RF Inputa,b 400 mV (Typical)
3.5 V (Max)
4 V (Absolute Max)
400 mV (Typical)
4 V (Max)
6 V (Absolute Max)
Amplifier RF Output Swing
(User-Adjustable)a
3 V to 7 V
RF Amplifier Gain (Fixed) 34 dB 30 dB
Rise/Fall Timec 35 ps 8 ps
Low Frequency Cutoff 100 kHz
  • Peak to Peak
  • Input is AC-Coupled. Maximum DC input allowable is ±15 V for the MX10B and ±10 V for the MX40B.
  • Large Signal, Digital Response
Linear (Analog) RF Amplifier Specifications
Item # Prefix MX35E
Bandwidth
35 GHz
RF Amplifier Gain (User-Adjustable) 10 dB to 23 dB
Amplifier RF Inputa,b 250 mV (Typical)
500 mV (Max)
700 mV (Absolute Max)
Low Frequency Cutoff 200 kHz
Amplifier RF Output Swinga 5 V (Max) for <3.5% THDc
7 V (Absolute Max)
Amplifier Linearity <3.5% THDc at 1 GHzd
Bit Rate (Maximum) 46 Gb/s
Typical Frequency Response
(Click Icon to View Graph)
MX35E Frequency Response
  • Peak to Peak
  • Input is AC-coupled. Maximum DC input allowable is ±10 V.
  • Total Harmonic Distortion (THD)
  • <500 mV Input, <5.0 V Output
Common Power Monitor and VOAa Specifications
Power Monitor Accuracyb ±0.5 dBm at Power Calibration Points
Power Monitor Resolutionb 0.01 dBm
Power Monitor Insertion Loss 0.1 dB (Typical) per Monitor
VOA Insertion Loss 0.4 dB (Typical)
VOA Response Time 1 s
  • Variable Optical Attenuator
  • Applies to each of the three internal power monitors.
Common Power and Environmental Specifications
Parameter Min Max
Main AC Voltage 100 VAC 250 VAC
Power Consumption - 60 VA
Line Frequency 50 Hz 60 Hz
Operating Temperature 10 °C 40 °C
Storage Temperature 0 °C 50 °C
Humiditya 5% Relative Humidity 85% Relative Humidity
  • Non-Condensing Environment
C-Band Laser Performance
Click to Enlarge

FM Noise Spectrum of the integrated tunable C-band and L-band lasers. The dither function helps stabilize the wavelength. Turning the dither off provides for lower noise. Please note that this option is not available for instruments with an integrated 1310 nm fixed-wavelength laser.
C-Band Tunable Laser Specifications (MX10B, MX40B, and MX35E)
Parameter Min Typical Max Unit
Wavelength Range 1527.6 - 1565.5 nm
Frequency Range 191.50 - 196.25 THz
Optical Output Power 12.5 13.5 14.5 dBm
Frequency Accuracy -1.5 - 1.5 GHz
Tuning Resolution - 50 - GHz
Tuning Speed (Between Wavelengths) - 10 - s
Side Mode Suppresion Ratio (SMSR) 40 55 - dB
Optical Signal Noise Ratio (OSNR) 40 60 - dB
Intrinsic Linewidth - 10 15 kHz
Relative Intensity Noise (RIN)a - - -145 dB/Hz
Back Reflection - - -14 dB
Polarization Extinction Ratio (PER) 18 - - dB
  • The noise in the optical power normalized to the average power level.
L-Band Tunable Laser Specifications (MX10B-LB, MX40B-LB, and MX35E-LB)
Parameter Min Typical Max Unit
Wavelength Range 1570.0 - 1608.8 nm
Frequency Range 186.35 - 190.95 THz
Optical Output Power 12.5 13.5 14.5 dBm
Frequency Accuracy -1.5 - 1.5 GHz
Tuning Resolution - 50 - GHz
Tuning Speed (Between Wavelengths) - 10 - s
Side Mode Suppresion Ratio (SMSR) 40 55 - dB
Optical Signal Noise Ratio (OSNR) 40 60 - dB
Intrinsic Linewidth - 10 15 kHz
Relative Intensity Noise (RIN)a - - -145 dB/Hz
Back Reflection - - -14 dB
Polarization Extinction Ratio (PER) 18 - - dB
  • The noise in the optical power normalized to the average power level.
1310 nm Fixed-Wavelength Laser Specifications (MX10B-1310, MX40B-1310, and MX35E-1310)
Parameter Min Typical Max Unit
Wavelength - 1310 - nm
Optical Output Power 12.5 13.5 14.5 dBm
Side Mode Suppresion Ratio (SMSR) 35 - - dB
Intrinsic Linewidth - 2 3 MHz
Polarization Extinction Ratio (PER) - 20 - dB


Alternate Laser Option

850 nm Fixed-Wavelength Laser Specifications (Substitute Internal Laser Option)a
  • Contact Tech Support to request the substitution of an an 850 nm fixed-wavelength laser.

System Overview

These Reference Transmitters are fully integrated and contain both the laser source and the lithium niobate (LiNbO3) Mach-Zehnder intensity modulator; the only required external input is the signal source to the Amplifier RF In port. Either the internal laser or an external laser source may be coupled to the Laser In port, which can be seen at the bottom-left corner of the diagram below. This port uses polarization maintaining (PM) fiber with light linearly polarized along the slow axis, as shown on the front panel of the instrument. Optical power is monitored in three places (Monitor 1, Monitor 2, and Monitor 3) for the purpose of enabling bias and power control. These power values are also available at the I/O port. Monitor 1 is at the laser input, Monitor 2 is at the output of the modulator, and Monitor 3 is at the final optical output.

Reference Transmitter Block Diagram
A Block Diagram of the Internal Setup of the High-Speed Reference Transmitters

Instrument Control

The graphical user interface (GUI) gives the user complete control over all instrument functionality. It is a resistive touchscreen display sensitive to both finger pressure and taps from a plastic stylus. The knob on the front panel of the housing can be used in place of the on-screen arrow buttons for quickly changing set-point values. Pressing (clicking) the knob will confirm a new set-point value. Additionally, the instruments can be driven using serial commands delivered via connectors on the rear panel.

The home screens of the MX10B and MX35E series are shown in Figures 1 and 2, respectively. They are organized into three main sections.  

Linear Reference Transmitter Main Menu
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Figure 2: Home Screen of the MX35E Series
Digital Reference Transmitter Main Menu
Click to Enlarge

Figure 1: Home Screen of the MX10B Series
(Identical to MX40B Series)
  • Left Column:
    • Buttons show the on/off status of the different instrument functions.
    • Tap a button to toggle the function on/off.
  • Middle Column:
    • Current operating parameters of each control function are shown.
    • Tap in this column to access the Settings page for each function.
  • Right Column:
    • Buttons provide access to various utility and help functions.
    • Tap to review and customize system settings.

The green dot that appears in the upper-right of the center column panels indicates that those functions are stable. The dot will blink if that function is still stabilizing. 

Functions and controls enabled by the GUI are further discussed in the following sections.

Laser and System Wavelength Settings

Reference Transmitter System Wavelength Selection Screen
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Figure 4: System Wavelength Selection Screen
Reference Transmitter Laser Settings GUI
Click to Enlarge

Figure 3: Laser Settings Screen

The laser setting screen shown in Figure 3 is accessed directly from the home screen. Each instrument includes a C- or L-band telecom-style laser that is tunable on the ITU 50 GHz grid or a 1310 nm fixed-wavelength laser. An 850 nm fixed-wavelength laser can be substituted by contacting techsupport@thorlabs.com. ITU Channel wavelengths are indexed for convenience; use the arrow buttons to step through the indices to select the desired wavelength. This screen also allows the user to control whether or not the dither feature (available for tunable C- and L-band lasers only) is used to stabilize the wavelength. Turning dither off results in lower phase and intensity noise (see the Specs tab for a representative plot), but doing so may also result in the wavelength drifting slightly over time. If an external laser is used, the internal laser can be turned off by tapping the laser button on the home screen.

If an external laser is used, it may be necessary to change the power monitor calibration settings. These instruments can be used at wavelengths anywhere between 1250 nm and 1610 nm, and calibration settings are supplied for three wavelengths: 1310 nm, 1550 nm, and 1590 nm. These wavelengths represent the centers of the O-Band, C-Band, and L-Band. The default calibration setting corresponds to the wavelength range of the internal laser. If operating outside that wavelength range, change the power monitor calibration settings by tapping the Menu button on the home page. Select the System Wavelength setting, shown in Figure 4, to change the power monitor calibration wavelength to the value closest to the wavelength of the laser source being used.

Reference Transmitter Digital Amplifier Voltage In vs. Voltage Out
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Figure 6: Limiting amplifiers in the MX10B and MX40B series provide high gain and a user-adjustable output swing in 0.1 V increments.
Reference Transmitter Digital Amplifier Settings Screen
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Figure 5: Digital RF Amplifier Settings Screen for the MX10B and MX40B Series

Limiting and Linear RF Amplifiers

Limiting RF Amplifier: The amplifiers used in the MX10B and MX40B series have “limiting” characteristics once a certain output voltage swing has been reached. This enables cleaner transmission of two-level digital signals. In addition, the peak-peak output swing can adjusted to control the extinction ratio (ER) of the output optical signal. These controls can be accessed from the Amplifier Settings page shown in Figure 5. The relationship between the input and output signals is shown in Figure 6. Small signals experience high gain, but as the signal level increases, the output signal swing is limited at the chosen set point.

For small input signals (before the amplifier limits), these instruments can actually be operated in analog mode. In this mode, the Output Swing is automatically set to its maximum value so that the linear gain region is maximized. Note that this only works if the input signal swing is kept small enough not to saturate the amplifier. See the manual for details.

The eye crossing point can be also adjusted during both digital and analog mode operation. A set point of 0 specifies a 50% crossing, which corresponds to the point midway between the signal's maximum and minimum values. Set points of -100 and +100 specify 35% and 65% crossings, respectively.

Reference Transmitter Linear Amplifier Voltage In vs. Voltage Out
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Figure 8: Linear amplifiers provide a linear relationship between voltage input and output. Different line slopes indicate different gain settings in the MX35E series. Gain is user-adjustable in 1 dB increments.
Reference Transmitter Linear Amplifier Settings Screen
Click to Enlarge

Figure 7: Linear RF Amplifier Settings Screen for the MX35E Series

Linear RF Amplifier: The amplifier used in the MX35E reference transmitter series is a linear amplifier that accurately reproduces the input signal with minimal distortion. In addition, the gain is adjustable and can be controlled from the Amplifier Settings page shown in Figure 7. This allows for linear amplification for a wide range of input signal levels before being applied to the RF input port of the modulator. Figure 8 shows how the gain setting changes the slope of the output vs. input signal relationship. Note, however, that the linear range of the whole system is still limited by the non-linear response of the lithium niobate modulator. See the specifications in the Specs tab and manual for signal limitations in this regard.

Although the instruments in the MX35E series are designed to be linear transmitters, the additional nonlinearities introduced by the lithium niobate (LiNbO3) modulator for large RF output signals can actually be an advantage in digital applications where compression can enhance the signal. Alternatively, for other applications, pre-compensation techniques can be used to provide a good extinction ratio and a linear response despite the non-linear behavior of the modulator. For digital applications, the gain of the amplifier should be adjusted so that the output swing of the amplifier is equal to, but not greater than, the Vpi voltage of the modulator. Please contact techsupport@thorlabs.com for details on these alternate applications. 

Modulator Bias Controller

Intensity Modulator Bias Control Settings
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Figure 10: Bias Settings Screen
LiNbO3 EO Modulator Transmission Function
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Figure 9: Bias Points for an Intensity Modulator, in which Vpi is the Half-Wave Voltage

There are four bias control modes, which provide the option of operating with fully automatic bias control or under manual control. Three of the four automated operating modes, Peak, Quadrature, and Null, reference the regions labeled on the modulation transmission function, which is illustrated in Figure 9. When one of these modes is selected, a dither tone is used to hold the modulator at the respective bias point. The dither tone is part of a lock-in approach that maintains a stable bias point by compensating for modulator drift, which occurs over time due to the temperature sensitivity of the modulator. The dither tone can be set to a frequency between 1 and 10 kHz, and the amplitude of the tone can also be selected. Quadrature mode gives the option of operating on either the positive or negative slope of the function.

For those applications that require an automated, but ditherless, approach to maintaining a stable bias set point, select the Constant Ratio mode. It is enabled by tapping the MAN function on the right of the screen shown in Figure 10 and configuring the Ratio Set Point and Slope values. This mode adjusts the bias voltage to maintain a chosen ratio between the intensity values reported by Monitor 1 and Monitor 2. The Slope setting allows the user to choose whether increasing voltage on the modulator increases or decreases the optical output power.

It can be useful to operate for brief periods of time at a bias fixed voltage and without a dither tone. A fixed bias voltage can applied in one of two ways. When operating in Quadrature, Peak, or Null modes, tapping the value of Dither will toggle it between on and off states. When dither is toggled off, the value of the fixed bias voltage is held at the most recent automated bias voltage. This enables the user to make quick measurements, without the dither tone present, while the modulator is biased at one of the common modulator transmission function set points. The Constant Bias mode can also be accessed by tapping the Mode value and then the MAN function on the right of the screen. This page allows either the automated Constant Ratio or fixed-voltage Constant Bias modes to be enabled and configured.

Variable Optical Attenuator

Reference Transmitter Variable Optical Amplifier Settings
Click to Enlarge

Figure 11: VOA Settings Screen

The VOA provides the means for adjusting and stabilizing the modulated optical output power. The VOA settings screen, which is shown in Figure 11, allows the user to choose between and adjust the parameters of the two operational modes. In Constant Attenuation mode, the attenuation level between the Return from Modulator input port and the Final Optical Output port is fixed, which allows power fluctuations at the input of the power controller to be transferred to the output. In Constant Output Power Mode, the final optical output power is held constant independent of the input fluctuations. In this mode, the VOA is effectively used as a power stabilizer. Tap the Step function button at the right of the screen to change the step size by which the arrows increment or decrement the set point values.

The VOA settings screen also allows the user to select the units used to report the power readings and parameters on all pages. Use the Power Units field to choose whether power values are reported as mW or dBm.

Rear Panel

The rear panel provides additional safety and utility functions such as the laser safety interlock and the power monitor output, RS-232, and USB ports. The USB interface is currently used only for firmware upgrades that are made available on Thorlabs website. Future revisions of the firmware will provide for remote control of the instrument's functions.

All units are shipped from Thorlabs with a shorting device that is already installed in the interlock connector, thus allowing the instrument to be operated normally right out of the box. To make use of the interlock feature, a 2.5 mm plug can be wired to the remote interlock switch and plugged into the back-panel interlock jack in place of the shorting plug. Electrical specifications for this function are provided in the manuals, which can be accessed by clicking on the red document icons () below.

Front Panels

MX10B Reference Transmitter Front Panel
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MX10B Reference Transmitter Front Panel
MX40B and MX35E Reference Transmitter Front Panel
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MX40B Reference Transmitter Front Panel
The front panels of the MX35E have the same format.
Front Panel of the MX10B Series
Callout Description
1 Touchscreen Display and Control
2 Value Adjustment Knob
3 Key Switch and Indicator Light for Internal Laser
4 Earth Ground Port for ESD Wrist Strap Banana Plug
5a Laser Out for Internal Laser Source,
Accepts PM Fiber with FC/PC Connector
6a Laser In to Modulator,
Accepts PM Fiber with FC/PC Connector
7b Optical Out: Final Output from Modulator
8 Amplifier Out: Signal from Internal Amplifier, SMA Female
9 Modulator RF In: Signal to Modulator, SMA Female
10 Amplifier RF In: Signal Input to Amplifier, SMA Female
11 On/Standby Button
  • Uses PM PANDA Fiber for Internal Connection
  • Uses SMF-28-Compatible Fiber for Internal Connection
Front Panel of the MX40B and MX35E Series
Callout Description
1 Touchscreen Display and Control
2 Value Adjustment Knob
3 Key Switch and Indicator Light for Internal Laser
4 Earth Ground Port for ESD Wrist Strap Banana Plug
5a Laser Out for Internal Laser Source,
Accepts PM Fiber with FC/PC Connector
6a Laser In to Modulator,
Accepts PM Fiber with FC/PC Connector
7b Optical Out: Final Output from Modulator
8 Amplifier RF In: Signal Input to Amplifier, K™ Female
9 On/Standby Button
  • Uses PM PANDA Fiber for Internal Connection
  • Uses SMF-28-Compatible Fiber for Internal Connection

Back Panel

Reference Transmitter Back Panel
Click to Enlarge

The back panel format is the same for each high-speed reference transmitter.
Back Panel of all Reference Transmitters
Callout Description
1a I/O Control Port
Outputs from Three Integrated Power Monitors
2 Laser Interlock Jack
3a RS-232 Control Port
4 USB Port (Type B)
5 AC Power Cord Connector
6 Fuse Tray
7 AC Power Switch
  • See the Pin Diagrams tab for pin assignments.

 I/O DB15 Connector

I/O DB15 Connector
The I/O connector provides analog outputs from the three power monitors.
Pin Description Pin Description
1 Power Monitor 1 9 Analog Ground
2 Power Monitor 2 10 Analog Ground
3 Power Monitor 3 11 Reserved for Future Use
4 Reserved for Future Use 12 Reserved for Future Use
5 Analog Ground 13 Monitor 1 Gain Indicator
6 Analog Ground 14 Monitor 2 Gain Indicator
7 Analog Ground 15 Monitor 3 Gain Indicator
8 Analog Ground - -

RS-232 Connector

RS-232 Connector
The RS-232 connector is included to support future remote operation that will be enabled by future firmware upgrades.
Pin Description
1 Not Connected
2 RS232 Input
3 RS232 Output
4 Not Connected
5 Digital Ground
6 Not Connected
7 Not Connected
8 Not Connected
9 Not Connected

USB Type B Connector

USB Type B Connector
The USB connector is provided for firmware upgrades and future remote operation.
High-Speed Reference Transmitter
Click to Enlarge

Each reference transmitter offers the option to customize the color of the underbody accent lights or turn them off.

Included with Thorlabs' High-Speed Reference Transmitters:

  • Optical Transmitter Main Unit
  • Power Cord According to Local Supply (Determined by Ordering Location, Not Shown)
  • PM Loop-Back Fiber Optic Cable
  • SMA Loop-Back RF Cable (For the MX10B Series Only, Not Shown)
  • Interlock Keys for Front Panel
  • 2.5 mm Interlock Pin (Pre-installed in Back Panel, Not Shown)
  • 1.25 A, 250 VAC Fuse (Not Shown)
  • USB Type A to Type B Cable, 6' Long (Not Shown)
Screen Capture of the TLX Laser Remote Control Tool Software V1.6
Click to Enlarge

The GUI of the Remote Control Software Tool 

Software for the MX10B, MX40B, and MX35E Series of Reference Transmitters

Control Our Reference Transmitters Remotely via Serial Commands
Serial commands sent to the MX10B, MX40B, and MX35E series of reference transmitters can control the functionality of the internal laser, RF amplifier, bias controller for the built-in modulator, and variable optical attenuator (VOA), as well as general system parameter settings. The commands can be sent from a computer running any operating system to the RS-232 port on the back panel of the reference transmitter. Computers running Windows® 7, or later versions of the operating system, can send serial commands to the USB port on the back panel of reference transmitter. The touchscreen interface remains active while the reference transmitter is controlled remotely. Descriptions of how to connect a controlling computer to the reference transmitter, the serial command set, and descriptions of each command are included in the Remote Control User Guide.

Application Demonstrating GUI-Based Remote Control of Our Reference Transmitters
The Remote Control Software Tool, which is available for download, is an example graphical user interface (GUI) provided for testing, demonstrating, and exploring the use of the different serial commands. This program is not required to operate the reference transmitter remotely. It opens a connection to the laser source and sends commands in response to buttons clicked by users. Commands sent to the reference transmitter, responses from it, and status information messages are logged to the three rectangular fields located beneath the buttons. Please see the Remote Control User Guide for more information. This program can be used as a basis for the development of custom applications. Please contact us to request the source code.

Updates for the MX10B and MX40B Series

Software Version 1.6.1 (September 26, 2017)

Firmware Update Version 1.6.2 (November 15, 2017)

The Remote Control Software Tool and firmware updates are available by clicking on the links below.

Software Download
Software Download

Updates for the MX35E Series

Software Version 1.6.1 (September 26, 2017)

Firmware Update Version 1.6.2 (November 15, 2017)

The Remote Control Software Tool and firmware updates are available by clicking on the links below.

Software Download
Software Download

Laser Safety and Classification

Safe practices and proper usage of safety equipment should be taken into consideration when operating lasers. The eye is susceptible to injury, even from very low levels of laser light. Thorlabs offers a range of laser safety accessories that can be used to reduce the risk of accidents or injuries. Laser emission in the visible and near infrared spectral ranges has the greatest potential for retinal injury, as the cornea and lens are transparent to those wavelengths, and the lens can focus the laser energy onto the retina. 

Laser Glasses Laser Curtains Blackout Materials
Enclosure Systems Laser Viewing Cards Alignment Tools
Shutter and Controllers Laser Safety Signs

Safe Practices and Light Safety Accessories

  • Thorlabs recommends the use of safety eyewear whenever working with laser beams with non-negligible powers (i.e., > Class 1) since metallic tools such as screwdrivers can accidentally redirect a beam.
  • Laser goggles designed for specific wavelengths should be clearly available near laser setups to protect the wearer from unintentional laser reflections.
  • Goggles are marked with the wavelength range over which protection is afforded and the minimum optical density within that range.
  • Laser Safety Curtains and Laser Safety Fabric shield other parts of the lab from high energy lasers.
  • Blackout Materials can prevent direct or reflected light from leaving the experimental setup area.
  • Thorlabs' Enclosure Systems can be used to contain optical setups to isolate or minimize laser hazards.
  • A fiber-pigtailed laser should always be turned off before connecting it to or disconnecting it from another fiber, especially when the laser is at power levels above 10 mW.
  • All beams should be terminated at the edge of the table, and laboratory doors should be closed whenever a laser is in use.
  • Do not place laser beams at eye level.
  • Carry out experiments on an optical table such that all laser beams travel horizontally.
  • Remove unnecessary reflective items such as reflective jewelry (e.g., rings, watches, etc.) while working near the beam path.
  • Be aware that lenses and other optical devices may reflect a portion of the incident beam from the front or rear surface.
  • Operate a laser at the minimum power necessary for any operation.
  • If possible, reduce the output power of a laser during alignment procedures.
  • Use beam shutters and filters to reduce the beam power.
  • Post appropriate warning signs or labels near laser setups or rooms.
  • Use a laser sign with a lightbox if operating Class 3R or 4 lasers (i.e., lasers requiring the use of a safety interlock).
  • Do not use Laser Viewing Cards in place of a proper Beam Trap.

 

Laser Classification

Lasers are categorized into different classes according to their ability to cause eye and other damage. The International Electrotechnical Commission (IEC) is a global organization that prepares and publishes international standards for all electrical, electronic, and related technologies. The IEC document 60825-1 outlines the safety of laser products. A description of each class of laser is given below:

Class Description Warning Label
1 This class of laser is safe under all conditions of normal use, including use with optical instruments for intrabeam viewing. Lasers in this class do not emit radiation at levels that may cause injury during normal operation, and therefore the maximum permissible exposure (MPE) cannot be exceeded. Class 1 lasers can also include enclosed, high-power lasers where exposure to the radiation is not possible without opening or shutting down the laser.  Class 1
1M Class 1M lasers are safe except when used in conjunction with optical components such as telescopes and microscopes. Lasers belonging to this class emit large-diameter or divergent beams, and the MPE cannot normally be exceeded unless focusing or imaging optics are used to narrow the beam. However, if the beam is refocused, the hazard may be increased and the class may be changed accordingly.  Class 1M
2 Class 2 lasers, which are limited to 1 mW of visible continuous-wave radiation, are safe because the blink reflex will limit the exposure in the eye to 0.25 seconds. This category only applies to visible radiation (400 - 700 nm).  Class 2
2M Because of the blink reflex, this class of laser is classified as safe as long as the beam is not viewed through optical instruments. This laser class also applies to larger-diameter or diverging laser beams.  Class 2M
3R Lasers in this class are considered safe as long as they are handled with restricted beam viewing. The MPE can be exceeded with this class of laser, however, this presents a low risk level to injury. Visible, continuous-wave lasers are limited to 5 mW of output power in this class.  Class 3R
3B Class 3B lasers are hazardous to the eye if exposed directly. However, diffuse reflections are not harmful. Safe handling of devices in this class includes wearing protective eyewear where direct viewing of the laser beam may occur. In addition, laser safety signs lightboxes should be used with lasers that require a safety interlock so that the laser cannot be used without the safety light turning on. Class-3B lasers must be equipped with a key switch and a safety interlock.  Class 3B
4 This class of laser may cause damage to the skin, and also to the eye, even from the viewing of diffuse reflections. These hazards may also apply to indirect or non-specular reflections of the beam, even from apparently matte surfaces. Great care must be taken when handling these lasers. They also represent a fire risk, because they may ignite combustible material. Class 4 lasers must be equipped with a key switch and a safety interlock.  Class 4
All class 2 lasers (and higher) must display, in addition to the corresponding sign above, this triangular warning sign  Warning Symbol

Janis Valdmanis, Ph.D. Optics
Ultrafast Optoelectronics
General Manager

Custom and OEM Options

When your application requirements are not met by our range of catalog products or their variety of user-configurable features, please contact me to discuss how we may serve your custom or OEM needs.  

Request a Demo Unit

Explore the benefits of using a Thorlabs high-speed instrument in your setup and under your test conditions with a demo unit. Contact me for details.

Contact Me

MX40B with cover removed
Click to Enlarge

 The MX40B Digital Reference Transmitter

Design, Manufacturing, and Testing Capabilities

Thorlabs' Ultrafast Optoelectronics Team designs, develops, and manufactures high-speed components and instrumentation for a variety of photonics applications having frequency responses up to 70 GHz. Our extensive experience in high-speed photonics is supported by core expertise in RF/microwave design, optics, fiber optics, optomechanical design, and mixed-signal electronics. As a division of Thorlabs, a company with deep vertical integration and a portfolio of over 20,000 products, we are able to provide and support a wide selection of equipment and continually expand our offerings.

Our catalog and custom products include a range of integrated fiber-optic transmitters, modulator drivers and controllers, detectors, receivers, pulsed lasers, variable optical attenuators, and a variety of accessories. Beyond these products, we welcome opportunities to design and produce custom and OEM products that fall within our range of capabilities and expertise. Some of our key capabilities are:

  • Detector and Receiver Design, to 70 GHz
  • Fiber-Optic Transmitter Design, to 70 GHz
  • RF & Microwave Design and Simulation
  • Design of Fiber-Optic and Photonics Sub-Assemblies
  • High-Speed Testing, to 70 GHz
  • Micro-Assembly and Wire Bonding
  • Hermetic Sealing of Microwave Modules
  • Fiber Splicing of Assemblies
  • Custom Laser Engraving
  • Qualification Testing

Overview of Custom and Catalog Products  

Our catalog product line includes a range of integrated fiber-optic transmitters, modulator drivers and controllers, detectors, pulsed lasers, and accessories. In addition to these, we offer related items, such as receivers and customized catalog products. The following sections give an overview of our spectrum of custom and catalog products, from fully integrated instruments to component-level modules.  

Fiber-Optic Instruments

To meet a range of requirements, our fiber-optic instruments span a variety of integration levels. Each complete transmitter includes a tunable laser, a modulator with driver amplifier and bias controller, full control of optical output power, and an intuitive touchscreen interface. The tunable lasers, modulator drivers, and modulator bias controllers are also available separately. These instruments have full remote control capability and can be addressed using serial commands sent from a PC.

  • Fiber-Optic Transmitters, to 70 GHz
  • Linear and Digital Transmitters
  • Electrical-to-Optical Converters, to 70 GHz
  • Modulator Drivers
  • Modulator Bias Controllers
  • C- and L-Band Tunable Lasers 

Customization options include internal laser sources, operating wavelength ranges, optical fiber types, and amplifier types.

Fiber-Optic Components

Our component-level, custom and catalog fiber-optic products take advantage of our module design and hermetic sealing capability. Products include detectors with frequency responses up to 50 GHz, and we also specialize in developing fiber-optic receivers, operating up to and beyond 40 GHz, for instrumentation markets. Closely related products include our amplifier modules, which we offer upon request, variable optical attenuators, microwave cables, and cable accessories.

  • Hermetically-Sealed Detectors, to 50 GHz
  • Fiber-Optic Receivers, to 40 GHz
  • Amplifier Modules
  • Electronic Variable Optical Attenuators
  • Microwave Cables and Accessories 

Customization options include single mode and multimode optical fiber options, where applicable, and detectors optimized for time or frequency domain operation.

Free-Space Instruments

Our free-space instruments include detectors with frequency responses around 1 GHz and pulsed lasers. Our pulsed lasers generate variable-width, nanosecond-duration pulses, and a range of models with different wavelengths and optical output powers are offered. User-adjustable repetition rates and trigger in/out signals provide additional flexibility, and electronic delay-line products enable experimental synchronization of multiple lasers. We can also adapt our pulsed laser catalog offerings to provide gain-switching capability for the generation of pulses in the 100 ps range.

  • Pulsed Lasers with Fixed 10 ns Pulse Duration
  • Pulsed Lasers with Variable Pulse Width and Repetition Rates
  • Electronic Delay Units to Synchronize NPL Series Pulsed Lasers
  • Amplified Detectors

Customization options for the pulsed lasers include emission wavelength, optical output powers, and sub-nanosecond pulse widths.


Posted Comments:
akg  (posted 2018-12-27 01:24:09.213)
I have one more query on MX40B. Is this possible to have it with higher extinction ratio. The mentioned specs are 13dB (Typical Maximum) and I am looking for extinction ratio of around 40dB. What is the maximum guaranteed extinction ratio that can be supported by Thorlabs? Request you to confirm the same.
YLohia  (posted 2018-12-27 10:27:20.0)
The limitation on extinction ratio for the MX40B is the lithium niobate intensity modulator. Our standard modulators only guarantee an extinction ratio of 13dB. It may be possible to get a higher extinction-ratio modulator, but ~40dB may be hard to do. Please email techsupport@thorlabs.com for future requests on customizations.
akg  (posted 2018-10-21 23:10:53.867)
Hello, My understanding is that the Amplifier RF input is single ended. I hope my understanding is correct. I raised this query because the specifications mentioned "Amplifier RF Input" as peak to peak. regards Atul
YLohia  (posted 2018-10-22 12:43:12.0)
Hello again Atul, the definitions that we’re using for the two terms in question are: Single Ended: The amplifier takes a single 50 Ohm input. This is in contrast to a differential input signal, which would be two 50 Ohm inputs that are positive and negative (inverting and non-inverting inputs). Voltage Peak to Peak: This references a measurement of the amplitude of the signal, as contrasting with Vrms or Vamp The MX40B has a single input, whose nominal and maximum input RF voltages we specify as a peak to peak voltage.
akg  (posted 2018-09-18 01:27:14.563)
Hello, In my application I want to connect MX40B optical output (modulated) to the optical input of MX40C. Can I get MX40B with Polarization Maintaining Fiber Output which can be connected with MX40C PMF input.
YLohia  (posted 2018-09-18 08:21:48.0)
Hello, you can use a single mode PM fiber (FC/PC connectorized) to connect the Optical Out port of the MX40B to the Laser In port of the MX40C. You can use the fiber supplied with the MX40C to do this. Alternately, if you require a longer length of fiber, please use our online custom fiber patch cable configuration tool here (https://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=2410) to select your custom length for the PM1550-XP fiber.
akg  (posted 2018-09-14 01:25:31.027)
Hello, I want to know how the linewidth of the laser inside MX10B/MX40B compare with that of Thorlab's SFL1550S. Which of the laser is better from linewidth perspective. From the data sheet the maximum linewidth for MX10B/MX40B and SFL1550S are 15KHz and 100KHz. Is the definition for the linewidth used in both the cases identical and laser of MX10B/MX40B better than that of SFL1550S? Please confirm.
YLohia  (posted 2018-09-17 11:07:53.0)
Hello, thank you for contacting Thorlabs. As far as linewidth goes, the laser in MX10B/MX40B would be smaller. The linewidth in both cases is characterized by the full width half max (FWHM). The 15 kHz and 100 kHz are the absolute max specs -- typically, the linewidth for both are better (~10 kHz and 50 kHz, respectively).
Transmitter Instruments and Tunable Lasers
Item # Speed Internal Laser Internal Modulator
(Type)
RF Amplifier
(Type)
Bias
Controller
Variable Optical
Attenuator (VOA)
Block
Diagram
Automatic Bias Controller
MBX N/A - - - yes yes
Tunable Telecom-Grade Laser Sources
TLX1 N/A C-Band, Tunable - - - yes
TLX2 N/A L-Band, Tunable
High-Speed Modulator Drivers
MX10A 12.5 Gb/sa - - Digital yes yes
MX40A 40 Gb/sa
High-Speed Optical Transmitters
MX10B 12.5 Gb/sa C-Band, Tunable Intensity Digital yes yes
MX10B-LB 12.5 Gb/sa L-Band, Tunable
MX10B-1310 12.5 Gb/sa 1310 nm, Fixed
MX10C 12.5 Gb/sa C-Band, Tunable Phase Digital - yes
MX10C-LB 12.5 Gb/sa L-Band, Tunable
MX10C-1310 12.5 Gb/sa 1310 nm, Fixed
MX35E 35 GHzb C-Band, Tunable Intensity Linear yes yes
MX35E-LB 35 GHzb L-Band, Tunable
MX35E-1310 35 GHzb 1310 nm, Fixed
MX40B 40 Gb/sa C-Band, Tunable Intensity Digital yes yes info
MX40B-LB 40 Gb/sa L-Band, Tunable
MX40B-1310 40 Gb/sa 1310 nm, Fixed
MX40C 40 Gb/sa C-Band, Tunable Phase Digital - yes
MX40C-LB 40 Gb/sa L-Band, Tunable
MX40C-1310 40 Gb/sa 1310 nm, Fixed
E-O Converters for VNA Applications
MX40G 40 GHzb C-Band, Tunable Intensity - yes yes
MX40G-LB 40 GHzb L-Band, Tunable
MX40G-1310 40 GHzb 1310 nm, Fixed
MX70G 70 GHzb C-Band, Tunable Intensity - yes yes
MX70G-LB 70 GHzb L-Band, Tunable
MX70G-1310 70 GHzb 1310 nm, Fixed
  • Maximum Supported Digital Bit Rate
  • Maximum Analog Bandwidth

Selection Guide for Transmitter Instruments

The capabilities of Thorlabs' extensive range of transmitter instruments are summarized in the text and table below. All members of this product series share a similar interface, as well as a common remote control command set.

Automatic Bias Controller
Thorlabs' fully-featured automatic bias controller provides complete and precise control of DC bias and optical output power for any fiber-coupled LiNbO3 EO intensity modulator, regardless of signal speed. Automatic bias controllers are ideal for use within a customized setup that uses an external laser, intensity modulator, signal source, and RF amplifier.

Tunable Telecom-Grade Laser Sources
Emitting in the C-band or the L-band, these lasers have narrow typical linewidths of 10 kHz. A frequency dither option aids in stabilizing the laser wavelength, and the integrated variable optical attenuator (VOA) provides optical output power control. These lasers are tunable in 50 GHz steps across the ITU frequency grid, and feature a 1 MHz step size fine-tune capability, as well.

High-Speed Modulator Drivers
With an operational wavelength range of 1250 nm to 1610 nm, each modulator driver provides control for an external fiber-coupled LiNbO3 EO modulator. Each modulator driver includes an RF amplifier with amplitude and eye-crossing controls and accepts an external drive signal source. Models with integrated automatic bias controllers are offered for use with intensity EO modulators.

High-Speed Optical Transmitters
Designed to provide fully-integrated solutions for high-speed light modulation, these systems are built around a LiNbO3 intensity or phase modulator. The MX10B, MX40B, MX10C, and MX40C series of systems include a digital (limiting) RF amplifier, which offers fixed gain and an adjustable output voltage swing. The MX35E series includes a high-bandwidth linear (analog) RF amplifier with adjustable gain, making it well suited for pulse amplitude modulation and related applications.

E-O Converters for VNA Applications
With our MX40G and MX70G series of E-O converters, any E-E vector network analyzer can be used to perform optical testing up to 40 GHz or 70 GHz respectively. The E-O converter is a fully-integrated solution that includes a laser, a modulator, and bias control.

Digital Reference Transmitters

 Key System Specificationsa
Item # MX10B Series MX40B Series
Amplifier Type Limiting (Digital)
Bit Rate (Maximum) 12.5 Gb/s 40 Gb/s
Internal Laser Output Powerb (Typ.) 13.5 dBm
External Input  Laser Wavelength Rangec 1250 nm - 1610 nm
Amplifier RF Output Swing (User-Adjustable) 3 V to 7 V
Low Frequency Cutoff 100 kHz
RF Amplifier Gain 34 dB 30 dB
Optical Extinction Ratio 13 dB (Typical Maximum)
Modulator Type Intensity
  • For complete specifications, see the Specs tab.
  • Includes C-band, L-band, and 1310 nm fixed-wavelength laser options. An 850 nm fixed-wavelength laser is also available upon request. Please contact Tech Support for details.
  • User-Provided
  • MX10B Series for Applications up to 12.5 Gb/s
  • MX40B Series for Applications up to 40 Gb/s
  • User-Adjustable RF Amplifier Output Swing
  • Mach-Zehnder Intensity Modulator
  • Fully Automatic or Manual Bias Control
    • Peak, Null, Quadrature, or Manual Set Points
    • Can Be Operated with or without Dither
  • Multiple Integrated Internal Laser Options*
    • C-Band Laser Tunable on ITU 50 GHz Grid
    • L-Band Laser Tunable on ITU 50 GHz Grid
    • 1310 nm Fixed-Wavelength Laser

These all-in-one digital reference transmitters integrate a Mach-Zehnder intensity modulator (MZM) with bias control, a tunable or fixed-wavelength laser source, limiting RF amplifier, and variable optical attenuator. The RF amplifier's output swing is user-adjustable from 3 V to 7 V. The MX10B series can operate up to 12.5 Gb/s and includes an external loop-back cable for connecting the RF output to the modulator input. This feature allows the user to use an external modulator driver, if desired (see the Front & Back Panel tab for details). The MX40B series supports bit rates up to 40 Gb/s but has a direct internal connection from the amplifier to the modulator. Both digital transmitters are well suited to many binary modulation formats, including RZ, NRZ, and OOK.

*An 850 nm fixed-wavelength laser is also available upon request. Please contact Tech Support for details.

Please note: Item #s ending in -LB or -1310 will ship from the US within 7 to 10 days of placing an order if all component parts are available.
Based on your currency / country selection, your order will ship from Newton, New Jersey  
+1 Qty Docs Part Number - Universal Price Available
MX10B Support Documentation
MX10B12.5 Gb/s Max Digital Reference Transmitter, C-Band Laser, Limiting Amplifier
$16,284.82
Today
MX10B-LB Support Documentation
MX10B-LB12.5 Gb/s Max Digital Reference Transmitter, L-Band Laser, Limiting Amplifier
$16,284.82
Lead Time
MX10B-1310 Support Documentation
MX10B-131012.5 Gb/s Max Digital Reference Transmitter, 1310 nm Laser, Limiting Amplifier
$16,284.82
Lead Time
MX40B Support Documentation
MX40B40 Gb/s Max Digital Reference Transmitter, C-Band Laser, Limiting Amplifier
$26,416.41
Today
MX40B-LB Support Documentation
MX40B-LB40 Gb/s Max Digital Reference Transmitter, L-Band Laser, Limiting Amplifier
$26,416.41
Lead Time
MX40B-1310 Support Documentation
MX40B-131040 Gb/s Max Digital Reference Transmitter, 1310 nm Laser, Limiting Amplifier
$26,416.41
Lead Time

Linear Reference Transmitters

 Key System Specificationsa
Item # MX35E Series
Amplifier Type Linear (Analog)
Bandwidth (Maximum) 35 GHz
Internal Laser Output Powerb (Typ.) 13.5 dBm
External Input  Laser Wavelength Rangec 1250 nm - 1610 nm
RF Amplifier Gain (User-Adjustable) 10 dB to 23 dB
Low Frequency Cutoff 200 kHz
Optical Extinction Ratio 13 dB (Typical Maximum)
Modulator Type Intensity
  • For complete specifications, see the Specs tab.
  • Includes C-band, L-band, and 1310 nm fixed-wavelength laser options. An 850 nm fixed-wavelength laser is also available upon request. Please contact Tech Support for details.
  • User-Provided

  • 35 GHz Analog Bandwidth
  • User-Adjustable RF Amplifier Gain
  • Mach-Zehnder Intensity Modulator
  • Fully Automatic or Manual Bias Control
    • Peak, Null, Quadrature, or Manual Set Points
    • Can Be Operated with or without Dither
  • Multiple Integrated Internal Laser Options*
    • C-Band Laser Tunable on ITU 50 GHz Grid
    • L-Band Laser Tunable on ITU 50 GHz Grid
    • 1310 nm Fixed-Wavelength Laser

These all-in-one linear reference transmitters integrate a Mach-Zehnder intensity modulator (MZM) with bias control, a tunable or fixed-wavelength laser source, linear RF amplifier, and variable optical attenuator. The RF amplifier's gain is user-adjustable from 10 dB to 23 dB. The MX35E series is designed for linear applications that require frequency response up to 35 GHz, which makes it compatible with high bit-rate modulation schemes that rely on multi-level encoding, such as PAM4. 

*An 850 nm fixed-wavelength laser is also available upon request. Please contact Tech Support for details.

Please note: Item #s ending in -LB or -1310 will ship from the US within 7 to 10 days of placing an order if all component parts are available.
Based on your currency / country selection, your order will ship from Newton, New Jersey  
+1 Qty Docs Part Number - Universal Price Available
MX35E Support Documentation
MX35E35 GHz Max Linear Reference Transmitter, C-Band Laser, Linear Amplifier
CALL
Today
MX35E-LB Support Documentation
MX35E-LB35 GHz Max Linear Reference Transmitter, L-Band Laser, Linear Amplifier
CALL
Lead Time
MX35E-1310 Support Documentation
MX35E-131035 GHz Max Linear Reference Transmitter, 1310 nm Laser, Linear Amplifier
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Lead Time
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