Optiwave software can be used in different industries and applications, including Fiber Optic Communication, Sensing, Pharma/Bio, Military & Satcom, Test & Measurement, Fundamental Research, Solar Panels, Components / Devices, etc..
OptiSystem is a comprehensive software design suite that enables users to plan, test, and simulate optical links in the transmission layer of modern optical networks.
OptiSPICE is the first circuit design software for analysis of integrated circuits including interactions of optical and electronic components. It allows for the design and simulation of opto-electronic circuits at the transistor level, from laser drivers to transimpedance amplifiers, optical interconnects and electronic equalizers.
OptiFDTD is a powerful, highly integrated, and user friendly CAD environment that enables the design and simulation of advanced passive and non-linear photonic components.
OptiBPM is a comprehensive CAD environment used for the design of complex optical waveguides. Perform guiding, coupling, switching, splitting, multiplexing, and demultiplexing of optical signals in photonic devices.
OptiFiber The optimal design of a given optical communication system depends directly on the choice of fiber parameters. OptiFiber uses numerical mode solvers and other models specialized to fibers for calculating dispersion, losses, birefringence, and PMD.
Emerging as a de facto standard over the last decade, OptiGrating has delivered powerful and user friendly design software for modeling integrated and fiber optic devices that incorporate optical gratings.
OptiConverge is a collaborative integration framework that seamlessly combines two or more Optiwave products (e.g., OptiSystem, OptiSPICE, OptiFDTD, etc.) and other third party products into unified solutions. Designed to streamline complex workflows, it empowers users to achieve their goals faster by harnessing the collective power of our trusted Optiwave tools.
Optiwave software can be used in different industries and applications, including Fiber Optic Communication, Sensing, Pharma/Bio, Military & Satcom, Test & Measurement, Fundamental Research, Solar Panels, Components / Devices, etc..
OptiSystem is a comprehensive software design suite that enables users to plan, test, and simulate optical links in the transmission layer of modern optical networks.
OptiSPICE is the first circuit design software for analysis of integrated circuits including interactions of optical and electronic components. It allows for the design and simulation of opto-electronic circuits at the transistor level, from laser drivers to transimpedance amplifiers, optical interconnects and electronic equalizers.
OptiFDTD is a powerful, highly integrated, and user friendly CAD environment that enables the design and simulation of advanced passive and non-linear photonic components.
OptiBPM is a comprehensive CAD environment used for the design of complex optical waveguides. Perform guiding, coupling, switching, splitting, multiplexing, and demultiplexing of optical signals in photonic devices.
OptiFiber The optimal design of a given optical communication system depends directly on the choice of fiber parameters. OptiFiber uses numerical mode solvers and other models specialized to fibers for calculating dispersion, losses, birefringence, and PMD.
Emerging as a de facto standard over the last decade, OptiGrating has delivered powerful and user friendly design software for modeling integrated and fiber optic devices that incorporate optical gratings.
OptiConverge is a collaborative integration framework that seamlessly combines two or more Optiwave products (e.g., OptiSystem, OptiSPICE, OptiFDTD, etc.) and other third party products into unified solutions. Designed to streamline complex workflows, it empowers users to achieve their goals faster by harnessing the collective power of our trusted Optiwave tools.
To create a basic project, perform the following procedure.
Step
Action
1
On the Tools toolbar, select Snap-to-Grid (see Figure 16).
2
From the Draw menu, select Linear Waveguide.
The cursor changes into a cross-hair when you move it into the project layout window.
3
To draw the first waveguide, in the project layout window, click in the left side of the project layout at Origin, drag the waveguide towards the right side of the project layout, and release (see Figure 16).
Note: Click the Select button to cancel waveguide creation mode. Create other waveguide shapes by selecting them and placing them in the layout as in steps 1 and 2. To delete a waveguide from the layout, select the waveguide and press Delete. For more information about the features of the waveguide designer, see the User’s Reference manual.
4
To edit the waveguide properties, from the Edit menu, select Properties, or double-click on the waveguide in the layout.
The Linear Waveguide Properties dialog box appears.
5
Use the steps illustrated above to create a layout similar to the one seen in Figure 16.
Figure 16: Layout design
6
Click the Ref. Index (n) 3D XY Plane View tab at the bottom of the layout window.
The refractive index view appears.
This view shows the refractive index distribution in the transverse (XY) plane at the position Z = 0. If your linear waveguide starts at Origin (see Figure 16), you should see the Channel waveguide we specified in the Profile Designer procedure Defining 2D and 3D channel profiles. Click on the Palette button to see the refractive index scale (see the first button in the toolbar shown in Figure 17). There are many other display options to choose from. Right-click on the layout to see a list of additional features.
Figure 17: Palette button
You should also become familiar with the Z button found on the Refractive Index View Type toolbar (see Figure 18). Use of this button allows you to move the Z position of the XY plane. You can adjust the Z position until you are satisfied that the refractive index is accurately portrayed in the 3D space. Ensure that you have created the correct shape, as this is the shape that will be passed to the simulator.