850nm To 1550nm Electro Optic Light Modulators
SCQ series electro-optic modulators have the features of low insertion loss, wide bandwidth, low half-wave voltage etc and are to be used in space optical communication, time base, pulse generator and quantum optics etc.
SCQ series electro-optic modulators are mainly divided into two groups: intensity modulators and phase modulators. Their working wavelengths are 780nm, 850nm, 1064nm, 1310nm, 1550nm and 2000nm.Other wavelengths are available upon request.
Definition of Part Numbers: SCQ-XX-WW-XG-F-FC
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XX: modulator type. AM is intensity modulator and PM is phase modulator.
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WW: operation wavelength, such as 850nm, 1064nm, 1310nm,1550nm and 2000nm
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XG: operation bandwidth, such as 2.5G, 10G, 40G
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F: In-out fiber such as PP (PM/PMF)
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FC: fiber connector such as FA (FC/APC), FP (FC/PC)
1. SCQ Series Intensity Modulators
| Part number | Operation wavelength nm | Min wavelength nm | Max wavelength nm | Bandwidth Hz | In/out fiber | Fiber connector |
| SCQ-AM-850-10G | 850 | 830 | 870 | 10G | PM/PM | FA, FP |
| SCQ-AM-1064-10G | 1060 | 980 | 1150 | 10G | PM/PM | FA, FP |
| SCQ-AM-1310-2.5G | 1310 | 1290 | 1330 | 2.5G | PM/PM | FA, FP |
| SCQ-AM-1550-2.5G | 1550 | 1530 | 1565 | 2.5G | PM/PM | FA, FP |
| SCQ-AM-1550-10G | 1550 | 1530 | 1565 | 10G | PM/PM | FA, FP |
| SCQ-AM-1550-20G | 1550 | 1530 | 1565 | 18G | PM/PM | FA, FP |
| SCQ-AM-1550-40G | 1550 | 1530 | 1565 | 28G | PM/PM | FA, FP |
1.1 SCQ-AM-1310 Series 1310nm Intensity Modulators
The LiNbO3 intensity modulator is widely used in high-speed optical communication system, laser sensing and ROF systems because of well electro-optic effect. The SCQ-AM series based on MZ structure and X-cut design, has stable physical and chemical characteristics, which can be applied both in laboratory experiments and industrial systems.
Features:
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Low insertion loss
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Bandwidth: 2.5GHz
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Low half-wave voltage
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Customization option
Applications:
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ROF systems
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Quantum key distribution
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Laser sensing systems
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Side-band modulation
Optical Parameters:
| Parameter | Symbol | Min | Typ | Max | Unit |
| Operating wavelength | | 1290 | 1310 | 1330 | nm |
| Insertion loss | IL | | 4 | 5 | dB |
| Optical return loss | ORL | | | -45 | dB |
| Switch extinction ratio @DC | ER@DC | 20 | 23 | | dB |
| Dynamic extinction ratio | DER | | 13 | | dB |
| Optical fiber (Input port) | | PM Fiber (125/250μm) | |
| Optical fiber (Output port) | | PM Fiber or SM Fiber (125/250μm) | |
| Optical fiber interface | | FC/PC,FC/APC Or Customization | |
Electrical Parameters:
| Parameter | Symbol | Min | Typ | Max | Unit |
| Operating bandwidth (-3dB) | S21 | | 2.5 | | GHz |
| Half-wave voltage (RF) | VΠ@1KHz | | 3 | 4 | V |
| Half-wave voltage (Bias) | VΠ@1KHz | | 3.5 | 4.5 | V |
| Electrical return loss | S11 | | -12 | -10 | dB |
| Input impedance (RF) | ZRF | 50 | W |
| Input impedance (Bias) | ZBIAS | 1M | W |
| Electrical interface | | SMA(f) | |
Limit Conditions:
| Parameter | Symbol | Unit | Min | Typ | Max |
| Input optical power | Pin, Max | dBm | | | 20 |
| Input RF power | | dBm | | | 28 |
| ias voltage | Vbias | V | -15 | | 15 |
| Operating temperature | Top | ℃ | -10 | | 60 |
| Storage temperature | Tst | ℃ | -40 | | 85 |
| Humidity | RH | % | 5 | | 90 |
Order Information:
| SCQ | AM | 13 | 2.5G | XX | XX |
| SCQ series | Type: AM---Intensity Modulator | Wavelength: 13---1310nm | Operation bandwidth: 2.5G---2.5GHz | In-Out Fiber type: PP---PM/PM | Optical connector: FA---FC/APC FP---FC/PC SP---Customization |
| PORT | Symbol | Note |
| In | Optical input port | PM Fiber (125μm/250μm) |
| Out | Optical output port | PM and SM Fiber option |
| RF | RF input port | SMA(f) |
| Bias | Bias control port | 1,2 Bias, 34-N/C |
2. SCQ Series Phase Modulators
| Part number | Operation wavelength nm | Min wavelength nm | Max wavelength nm | Bandwidth Hz | In/out fiber | Fiber connector |
| SCQ-PM-780-10G | 780 | 760 | 800 | 10G | PM/PM | FA, FP |
| SCQ-PM-850-10G | 850 | 780 | 890 | 10G | PM/PM | FA, FP |
| SCQ-PM-1064-300M | 1060 | 980 | 1150 | 300M | PM/PM | FA, FP |
| SCQ-PM-1064-10G | 1060 | 980 | 1150 | 10G | PM/PM | FA, FP |
| SCQ-PM-1310-10G | 1310 | 1290 | 1330 | 10G | PM/PM | FA, FP |
| SCQ-PM-1550-300M | 1550 | 1530 | 1565 | 300M | PM/PM | FA, FP |
| SCQ-PM-1550-10G | 1550 | 1530 | 1565 | 10G | PM/PM | FA, FP |
| SCQ-PM-1550-20G | 1550 | 1530 | 1565 | 20G | PM/PM | FA, FP |
2.1 SCQ-PM Series 1310nm Electro-optical Phase Modulators
The LiNbO3 phase modulator is widely used in a high-speed optical communication system, laser sensing, and ROF systems because of well electro-optic effect. The SCQ-PM-1310 series, based on Ti-diffused technology, has stable physical and chemical characteristics, which can meet most applications in laboratory experiments and industrial systems.
Features:
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Low insertion loss
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Polarization-maintaining
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Low half-wave voltage
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Dual-polarization option
Application:
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Optical communication
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Quantum key distribution
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Frequency shifting
Optical parameters:
| Parameter | Symbol | Min | Typ | Max | Unit |
| Operating wavelength | l | 1290 | 1310 | 1330 | nm |
| Insertion loss | IL | | 3.5 | 4 | dB |
| Optical return loss | ORL | | | -45 | dB |
| Polarization extinction ratio | PER | 20 | | | dB |
| Optical fiber | Input port | | PM fiber(125/250μm) | |
| Output port | | PM fiber(125/250μm) | |
| Optical fiber interface | | FC/PC,FC/APC Or Customization | |
Electrical Parameters:
| Parameter | Symbol | Min | Typ | Max | Unit |
| Operating bandwidth(-3dB) | S21 | 10 | 12 | | GHz |
| Half-wave voltage @50KHz | VΠ | | 2.7 | 3 | V |
| Electrical return loss | S11 | | -12 | -10 | dB |
| Input impedance | ZRF | 50 | |
| Electrical interface | | SMA(f) | |
Limit parameters:
| Parameter | Symbol | Unit | Min | Typ | Max |
| Input optical power | Pin,Max | dBm | | | 20 |
| Input RF power | | dBm | | | 28 |
| Operating temperature | Top | ℃ | -10 | | 60 |
| Storage temperature | Tst | ℃ | -40 | | 85 |
| Humidity | RH | % | 5 | | 90 |
Ordering Information:
| SCQ | PM | 13 | XX | XX | XX |
| SCQ series | Modulator type: PM--- Phase modulator | Operating wavelength: 13---1310nm | Operating bandwidth: 10---10G | Input & output fiber: PM/PM | Connector: FA ---FC/APC FP ---FC/PC SP---user specified |
| PORT | Symbol | Note |
| In | Optical input port | PM Fiber (125μm/250μm) |
| Out | Optical output port | PM and SM Fiber option |
| RF | RF input port | SMA(f) |
| Bias | Bias control port | 1,2 Bias, 34-N/C |
3. Drivers
3.1 SCQ-RF Series Drivers
SCQ-RF broadband RF amplifier (or called as driver) is a desktop instrument specially designed for high-speed lithium niobate electro-optic modulator. This instrument can amplify the small high-speed signal level to the higher level that can drive the modulator, thus driving the lithium niobate (LiNbO3) electro-optic modulator to work, and has good gain flatness in the broadband range.
Features:
Applications:
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10/20/40G optical modulating system
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Fiber optic testing system
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Optical fiber sensing system
Parameters of SCQ-RF-40 Driver
| Parameter | Unit | Min | Typ | Max |
| Transmission rate | Gb/s | 0.0001 | | 44 |
| Operating frequency range | Hz | 50K | 40G | |
| Output voltage magnitude | V | 7 | 8 | 9 |
| Gain margin | V | 0.3 | 0.4 | 0.6 |
| Regulation precision | dB | 24 | 27 | 35 |
| Output power P1dB | V | | 0.1 | |
| Gain variation(ripple) | dBm | 20 | | |
| Rise/fall time | dB | | ±1.5 | |
| Additional jitter | ps | | 8 | 12 |
| Input/output impedance | ps | | 0.42 | |
| Input voltage amplitude | | - | 50 | - |
| Input voltage standing-wave ratio VSWR (75k to 10GHz) | | | 1.6:1 | 2.25:1 |
| Output voltage standing-wave ratio VSWR | | | 2:1 | 3:1 |
| Boundary dimension(L x W x H) | mm | 270 x 200 x 70 |
| Operating voltage | V | AC 220 |
| RF interface | | V(f)-V(f) |
Limit Conditions
| Parameter | Unit | Min | Typ | Max |
| Input voltage amplitude | V | | | 1 |
| Working temperature | ºC | -10 | | 60 |
| Storage e temperature | ºC | -40 | | 85 |
| Humidity | % | 5 | | 90 |
Eye Diagram
Ordering Information:
| SCQ | RF | XX | XX | X |
| SCQ series drivers | RF amplifier | Operating rate: 10---10Gbps 20---20Gbps 40---40Gbps | Output characteristic: Blank---Standard HO---High voltage output RZ---RZ signal amplification | Footprint: D---Table model |
3.2 MZM Bias Controller
The bias controller is specially designed for Mach-Zehnder modulators to ensure a stable operation state in various operating environments. Based on its fully digitized signal processing method, the controller can provide highly stable performance. The controller injects a low frequency, low amplitude dither signal together with bias voltage into the modulator. It keeps reading the output from the modulator and determines the condition of the bias voltage and the related error. A new bias voltage will be applied afterwards according to the previous measurement. In this way, the modulator is ensured to work under proper bias voltage.
Features:
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Bias voltage control on Peak/Null/Q+/Q−
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Bias voltage control on arbitrary point
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Ultra precise control: (1) 50dB maximum extinction ratio on Null mode; (2) ±0.5◦ accuracy on Q+ and Q− modes
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Low dither amplitude: (1) 0.1% Vπ at NULL mode and PEAK mode; (2) 2% Vπ at Q+ mode and Q− mode
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High stability: with fully digital implementation
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Low profile: 40mm(W) × 30mm(D) × 10mm(H)
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Easy to use: (1) Manual operation with mini jumper; (2) Flexible OEM operations through MCU UART2
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Two different modes to provide bias voltage: (1) Automatic bias control; (2) User defined bias voltage
Application:
Ordering Information
Part No.: SCQ-RF-BC
Remark: (1) The highest extinction ratio depends on and cannot exceed modulator maximum extinction ratio. (2) UART operation is only available on some version of the controller.
Performance:
Maxim DC Extinction Ratio:
In this experiment, no RF signals were applied to the system. Pure DC extinction has been measured.
(1) Figure 3 demonstrates the optical power of modulator output, when modulator controlled at Peak point. It shows 3.71dBm in the diagram.
(2) Figure 4 shows the optical power of modulator output, when modulator controlled at Null point. It shows -46.73dBm in the diagram. In real experiment, the value varies around -47dBm; and -46.73 is a stable value.
(3) Therefore, the stable DC extinction ratio measured is 50.4dB.
Requirements for High Extinction Ratio:
(1) System modulator must have high extinction ratio. Characteristic of system modulator decides the maximum extinction ratio can be achieved.
(2) Polarization of modulator input light shall be taken care of. Modulators are sensitive to polarization. Proper polarization can improve extinction ratio over 10dB. In lab experiments, usually a polarization controller is needed.
(3) Proper bias controllers. In our DC extinction ratio experiment, 50.4dB extinction ratio has been achieved. While the datasheet of the modulator manufacture only lists 40dB. The reason of this improvement is that some modulators drift very fast. Our SCQ-RF-BC-ANY bias controllers update the bias voltage every 1 second to ensure fast track response.
Specifications:
| Parameter | Min | Typ | Max | Unit | Conditions |
| Control Performance |
| Extinction ratio | | MER 1 | 50 | dB | |
| CSO2 | −55 | −65 | −70 | dBc | Dither amplitude: 2%Vπ |
| Stablization time | | 4 | | s | Tracking points: Null & Peak |
| Stablization time | | 10 | | s | Tracking points: Q+ & Q- |
| Electrical |
| Positive power voltage | +14.5 | +15 | +15.5 | V | |
| Positive power current | 20 | | 30 | mA | |
| Negative power voltage | -15.5 | -15 | -14.5 | V | |
| Negative power current | 2 | | 4 | mA | |
| Output voltage range | -9.57 | | +9.85 | V | |
| Output voltage precision | | 346 | | µV | |
| Dither frequency | 999.95 | 1000 | 1000.05 | Hz | Version: 1kHz dither signal |
| Dither amplitude | | 0.1%Vπ | | V | Tracking points: Null & Peak |
| Dither amplitude | | 2%Vπ | | V | Tracking points: Q+ & Q- |
| Input optical power3 | -30 | | -5 | dBm | |
| Input wavelength | 780 | | 2000 | nm | |
1 MER refers to Modulator Extinction Ratio. The extinction ratio achieved is typically the extinction ratio of modulator specified in modulator datasheet.
2 CSO refers to composite second order. To measure CSO correctly, the linear quality of RF signal, modulators and receivers shall be
ensured. In addition, the system CSO readings may vary when running at different RF frequencies.
3 Please be noted that input optical power does not correspond to the optical power at selected bias point. It refers to the maximum optical power that the modulator can export to controller when bias voltage ranges from −Vπ to +Vπ .
| Group | Operation | Explanation |
| Photodiode1 | PD: Connect MZM photodiode’s Cathode | Provide photocurrent feedback |
| GND: Connect MZM photodiode’s Anode |
| Power | Power source for bias controller | V-: connects the negative electrode |
| V+: connects the positive electrode |
| Middle probe: connects the ground electrode |
| Reset | Insert jumper and pull out after 1 second | Reset the controller |
| Mode Select | Insert or pull out the jumper | no jumper: Null mode; with jumper: Quad mode |
| Polar Select2 | Insert or pull out the jumper | no jumper: Positive Polar; with jumper: Negative Polar |
| Bias Voltage | Connect with the MZM bias voltage port | OUT and GND provide bias voltages for modulator |
| LED | Constantly on | Working under stable state |
| On-off or off-on every 0.2s | Processing data and searching for controlling point |
| On-off or off-on every 1s | Input optical power is too weak |
| On-off or off-on every 3s | Input optical power is too strong |
| UART | Operate controller via UART | 3.3: 3.3V reference voltage |
| GND: Ground |
| RX: Receive of controller |
| TX: Transmit of controller |
| Control Select | Insert or pull out the jumper | no jumper: jumper control; with jumper: UART control |
1 Some MZ modulators have internal photodiodes. Controller setup should be chosen between using controller’s photodiode or using modulator’s internal photodiode. It is recommended to use controller’s photodiode for lab experiments for two reasons. Firstly, controller photodiode has ensured quality. Secondly, it is easier to adjust the input light intensity. Note: If using modulator’s internal photodiode, please make sure that the output current of photodiode is strictly proportional to input power.
2 Polar pin is used to switch the control point between Peak and Null in Null control mode(determined by Mode Select pin) or Quad+ and Quad- in Quad control mode. If jumper of polar pin is not inserted, the control point will be Null in Null mode or Quad+ in Quad mode. Amplitude of RF system will also affect the control point. When there is no RF signal or RF signal amplitude is small, controller is able to lock the work point to correct point as selected by MS and PLR jumper. When the RF signal amplitude exceeds certain threshold, polar of the system will be changed, in this case, the PLR header should be in the opposite state, i.e. the jumper should be inserted if it is not or pulled out if it is inserted.
Typical Application:
The controller is easy to use as follows:
Step1. Connect 1% port of the coupler to the photodiode of the controller.
Step2. Connect bias voltage output of the controller (through SMA or 2.54mm 2-pin header) to bias port of the modulator.
Step3. Provide controller with +15V and -15V DC voltages.
Step4. Reset the controller and it will start to work.
NOTE. Please be ensured that RF signal of the whole system is on before resetting the controller.
