Uncooled Operation of Microresonator Devices
This invention removes the need to provide temperature control for an optical time delay chip, which is usually provided by a thermo-electric-cooler, in order to significantly reduce the power dissipation of the device and allow ‘uncooled’ operation. Uncooled operation is achieved by monitoring the temperature of the chip, and changing the tuning of each microresonator within the device in order to continue providing the required time delay as the temperature is varied. This invention takes advantage of the fact that microresonators provide a series of resonant wavelengths over a wide wavelength range, so that the closest resonance wavelength below the operating wavelength can always be tuned up to that wavelength. When the device temperature changes, this is accounted for by both the choice of resonance wavelengths and the tuning for each of the microresonators in the device, in order to keep the correct tunable delay.
This patent application is a continuation-in-part of the U.S. patent application Ser. No. 13/044,669 filed on Mar. 10, 2011.
STATEMENT REGARDING FEDERAL SPONSORED RESEARCH AND DEVELOPMENTThis invention was made with U.S. Government support under Contract W31P4Q-09-C0298 with DARPA MTO SBIR Project, and the U.S. Government has certain rights in the invention.
FIELD OF INVENTIONThis invention relates to an active array antenna system for use in microwave photonics. More particularly it addresses tunable delays to control phased array antennas.
BACKGROUNDOne of the major issues of optical microresonator devices is that their operating wavelength (or conversely, frequency) is temperature sensitive, making it necessary to temperature control the device for many practical applications. As an example, consider an optical microresonator 140 coupled to a single optical waveguide 130 (shown in
An example of an optical time delay device incorporating a series of independent optical microresonators is shown in
The Balanced SCISSOR approach requires that the overall chip temperature be held at a fixed temperature, typically by using a Thermo-Electric-Cooler (TEC) to heat or cool the device, plus a thermistor on or close to the device to measure its temperature and provide feedback to control the TEC. If the tuning range of the microresonators is less than the FSR, then in order for the device to be able to operate at any wavelength it is necessary to change the temperature of the entire chip to first place the resonances in the correct position relative to the operating wavelength, before the microresonators are then tuned to the operating wavelength. The use of a TEC to control the temperature of the device adds significant power dissipation to the overall packaged device, as well as additional size and cost. If at all possible it would be of great utility to remove the need to use a TEC for correct device operation.
SUMMARYThe present invention removes the need to provide temperature control of an optical time delay chip, which is usually provided through the use of a thereto-electric-cooler (TEC) and temperature sensor in a feedback loop, in order to significantly reduce the power dissipation of the time delay device and allow it to be operated in an ‘uncooled’ mode. The need for temperature control of the chip is removed by monitoring the temperature of the chip, and then modifying the tuning of each microresonator within the time delay device in order to continue providing the required time delay even as the temperature is varied. This approach takes advantage of the fact that the microresonators include a series of resonant wavelengths over a wide wavelength range, separated by the FSR of the microresonator, so that the closest resonance wavelength below the operating wavelength can always be chosen to be tuned up to the operating wavelength. When the device temperature changes, this is accounted for in both the choice of resonant wavelength and tuning of the microresonators in order to keep the correct tunable delay.
In addition to monitoring the temperature of the overall time delay device, the use of temperature sensors at each microresonator is described. The invention includes the measurement of optical power before and after the time delay device, to allow for self testing of the device, and also to better optimize the alignment of microresonator resonant wavelengths with the operating wavelength of the device. A further element of the invention includes a direct measurement of the optical delay provided by the device, by measuring the phase delay between the microwave signals before and after the time delay device, and then utilizing this phase delay in a feedback loop to compare the requested and measured time delay, and minimize the difference.
A further object of this invention leaves the time delay device operation the same irrespective of its operating temperature, but then modifies the operating wavelength used in the system to keep this laser source wavelength the same as the operating wavelength of the time delay device—which is varying with ambient temperature, therefore supporting uncooled operation of the time delay device.
The idea of this invention is to remove the need for temperature control of the time delay chip, while it provides a tunable time delay. The approach is based on the necessity to keep the time delay of a given microresonator equal to a given value independent of the temperature of the whole chip.
This is accomplished by first ensuring a large enough tuning range of the microresonator resonance frequencies, which must be larger than (1+Delta)×FSR, where ‘Delta’ is a value from 0 to 1. Next, the chip temperature is allowed to float with the ambient temperature, while utilizing an algorithm to calculate the temperature tuning (heating) required for each microresonator to provide the correct resonance frequency based on the required delay and the overall chip temperature. As long as the temperature of the chip is varying much slower than the update rate of the required chip delay value, the constant switching from one delay value to the next can encompass the small chip temperature change occurring since the last switching event, and when necessary choose to tune an adjacent resonance to the correct wavelength to continue tuning the delay as required.
The ‘Delta’ parameter depends on the variation in resonance wavelengths at a fixed device temperature for the multiple microresonators on one device, which often occurs due to imperfections in lithography and processing, even if all resonances are designed to be at the same wavelength. If all resonances are exactly lined up in wavelength when the chip is at a fixed temperature, then Delta is zero. If there is a variation of resonance wavelengths (typical with current technology, as shown in
The operation of this invention is described as follows: An optical time delay device 500 incorporating a series of independent optical microresonators 540 is shown in
The microresonators (typically an even number) are split into two sets for use in the Balanced SCISSOR approach (U.S. Pat. No. 7,831,119 B2), which provides tunable optical delay with wide bandwidth and low distortion to a signal. The two sets of microresonators are initially aligned with the signal wavelength, which is achieved by first setting the overall chip temperature, so that all of the microresonators provide resonances that are below the operating wavelength of the signal (
Consider an initial ambient temperature, T1, where the two sets of resonances are aligned around the operating wavelength of the system, as seen in
Using this same concept; a device with a broad tuning capability, >(1+Delta)*FSR, and using the algorithm described above to choose which microresonator resonance to tune to the operating wavelength, the device can support any operating wavelength within the broad range where the device is designed to operate. This provides a device that can perform over both arbitrary ambient temperature and arbitrary operating wavelength, over the large ranges where the device can operate. The ambient temperature range may be very large, limited only by the materials used in the waveguides and heaters, e.g. −55° C. to +125° C. or greater. The operating wavelength range will depend on the performance of the optical waveguide and the coupler to the microresonator, supporting wide operating wavelengths e.g. the C+L. Bands around 1550 nm.
In practice, the overall chip temperature will be measured (e.g. with a thermistor) 504 and used to calculate the heater drive for each microresonator based on calibration information, such as stored in a look-up table. Additionally, temperature values measured for each individual microresonator can also be used to calculate the heater drive required for each individual microresonator; these temperature values can be obtained by integrating a temperature sensing element at each microresonator 508. This could be as simple as monitoring the resistance of the heater for that element, which varies with temperature, e.g. for a specific voltage applied to the heater element the current can be measured on the circuit board and the voltage and current values used to deduce the temperature of the heater and the microresonator itself.
Providing microresonators with the required tuning range, (1+Delta)*FSR, can be achieved by utilizing efficient heaters to provide a significant temperature tuning range, by using a waveguide material with significant temperature tuning characteristics, and/or by reducing the FSR of the microresonator by increasing the microresonator's waveguide length. These requirements have been shown in a number of materials and devices used for microresonators, such as silicon or silicon nitride based waveguide microresonator devices.
The concept will also work with alternative tuning mechanisms other than thermal tuning, to change the resonance wavelength of the microresonators by another means 542, including carrier modulation, the use of liquid crystal, polymer or other materials to change the effective index of the waveguide, or mechanical variations to change the resonance wavelengths; in all cases, what is required is sufficient tuning range to support arbitrary chip temperatures and operating wavelengths, i.e. tuning ≥(1+Delta)*FSR.
The thermal tuning approach described in this continuation, which at times requires for the tuning of one microresonator to be moved from one resonance to the next resonance, may violate the Balanced Thermal tuning concept (described in US # U.S. Pat. No. 8,406,586 B2), by changing the overall heating applied to the chip and causing a thermal transient to occur. This can be overcome by including one or more additional ballast heaters to the time delay chip, 506, that are not connected to any optical microresonator, rather used only to carry out fine balancing of the heat added to the chip, keeping it constant and avoiding or reducing thermal transients.
Another approach to supporting uncooled operation of the time delay device as the temperature of the device changes is to tune the operating wavelength of the laser used with the time delay device, in order to track the operating wavelength of the time delay device. This approach is shown in
Additionally, a small portion of the output optical signal from the time delay device can be tapped off, 940, and the power of that signal monitored with an optical detector 950. This tap and monitor detector could be alternatively integrated onto the time delay chip, rather than external as shown in
In addition to monitoring the temperature of the optical time delay device, in order to know the resonance frequencies of the microresonators within the device (e.g. from a lookup table), this invention includes the idea of monitoring the optical signal passing through the device, either on the optical time delay chip or after the chip. In one embodiment, the microresonator based time delay device could include a coupler in its output waveguide, taking a small percentage of the output optical power to an integrated photodetector. The power to the photodetector can be monitored; this power (loss) is proportional to the optical delay in the device. The measurement path may include optical filters with frequency dependent transmission characteristics, integrated on to or separate from the time delay device. A second measurement path could include a coupler on the input to the time delay device in order to couple a small percentage of the input signal, which can also be measured at a photodetector with or without an intermediate optical filter. This measured information can be used, together with an algorithm to move the resonance wavelengths of the different microresonators, in order to carry out self-testing of the device. The same measurement information can also be used in a feedback loop in order to optimally align the laser wavelength and microresonator resonances, e.g. maximizing or minimizing signal power, or adding a dither frequency and using it to place the resonances at the correct wavelength (or conversely placing the laser wavelength at the correct place relative to the resonances).
For highest performance of the time delay device it is desirable to provide a control loop that can measure the actual delay achieved by the device, compare that with the requested delay value, and make adjustments to provide the requested delay value. For fast operation and compactness it is desirable to have this control loop in close proximity to the delay line, eventually, and preferably, on the chip itself. Measurement of the time delay is difficult; it can be done with a short optical pulse, however, this involves the inclusion of an analog-to-digital converter—similar to having a dedicated fast digital sampling oscilloscope with associated processor in order to determine the time delay. This invention utilizes the fact that the time delay of an optical signal is equivalent to the phase delay of the modulating microwave signal. The scheme is shown in
The operation of the phase detector 830 is described in (G. Ohm, M. Alberty IEEE Transactions on Microwave Theory And Techniques, Vol. Mtt-29, No. 7, July 1981).
The measured delay time 880 is input to the controller 840 where it is compared with the requested delay time 870, and used to calculate new drive levels for the heaters of the microresonators in the time delay device; this loop is iterated until the measured delay time becomes equal to the requested delay time.
In order to operate the device uncooled over a wide ambient temperature range, while maintaining one of the key requirements of a tunable optical delay device—low optical loss, it is important to keep the coupling loss of light from an optical fiber into the device and out of the device very low even as the temperature varies. This is difficult in devices with the small optical waveguide dimensions needed to produce optical microresonators for time delay. One way to overcome this issue, as shown in
Although several exemplary embodiments have been herein shown and described, those of skill in the art will recognize that many modifications and variations are possible without departing from the spirit and scope of the invention, and it is intended to measure the invention only by the appended claims.
Claims
1. An optical device, comprising:
- a chip without chip temperature control, the chip having M loop resonators (M≥2), the optical device receiving incoming light at an operating wavelength and outputting modified light, wherein a peak delay of the device is larger than a peak delay of a single microresonator;
- each microresonator having a mean which provides a tuning capability ≥(1+Delta)·FSR, where Delta describes a variation in resonance wavelengths of the microresonators, 1≥Delta≥0; and M means adjusting the resonant wavelengths of the microresonators relative to the operating wavelength of the device.
2. The device of claim 1, wherein the means provide enough tuning capability to shift at least one of resonances of a given microresonator anywhere within one FSR value from the operating wavelength.
3. The device of claim 1, further comprising sensors to measure a chip temperature, which is then used to calculate a tuning required for each microresonator.
4. The device of claim 3, wherein the chip temperature is measured with a thermistor.
5. The device of claim 1, wherein the means are heaters.
6. The device of claim 5, wherein the temperature of each microresonator is measured by a separate temperature sensor.
7. The device of claim 5, wherein the temperature of each microresonator is measured by the resistance of the corresponding heater itself.
8. The device of claim 1, further comprising a ballast heater, which provides a constant thermal load for the chip to avoid thermal transients and therefore keeping the balanced thermal tuning.
9. The device of claim 1, in which the microresonator resonance wavelength tuning is obtained by mechanisms other than thermal tuning, including carrier density modulation, liquid crystals, polymer or other materials to change the effective index of the waveguide, or mechanical variations to change the resonance wavelengths.
10. The device of claim 1, further comprising beam expanders on input and output waveguides to significantly reduce variations of a coupling loss due to mechanical movements in optical coupling elements that occur as temperature changes.
11. The device of claim 1, further comprising a tuner that changes a wavelength of the incoming light to compensate for a temperature drift of the chip.
12. The device of claim 11, further comprising sensors to measure a chip temperature, being connected to a processing unit, the processing unit uses signals from the temperature sensors to calculate a tuning required for the wavelength of the incoming light.
13. The device of claim 11, further comprising a detector to measure a power of the outputted light, the detector being connected to the tuner via a feedback loop to adjust the tuner to keep the incoming wavelength at a value providing the compensation for the temperature drift.
14. The device of claim 1, further comprising a first detector to detect an instant power of the incoming light and a second detector to detect an instant power of the outcoming light, both detectors being connected to a microwave phase detector, the microwave phase detector measuring a relative phase between outputs of the first and the second detectors and sending an obtained measured result to a controller, the controller comparing the obtained result with a required time delay and generating control signals to adjust resonant frequencies of each microresonator.
15. The device of claim 1, further comprising a first detector to detect an instant power of the incoming light and a second detector to detect an instant power of the outcoming light, where these two signals are utilized in a controller to provide self testing of the device when not in operation, and to provide optimum alignment of the microresonator resonance wavelengths when in operation as a tunable delay device.
16. A method for delaying of a signal imposed on a light beam, comprising:
- inserting the light beam into a time delay chip having M microresonators, M≥2;
- controlling resonant wavelengths of M resonators, by tuning within a range R≥(1+Delta)·FSR, where Delta describes a variation in resonance wavelengths of the microresonators, 1≥Delta≥0; thus achieving maximum available range of time delay for an output beam and cancelling of a temperature drift of a time delay chip.
17. The method of claim 16, wherein controlling the resonant wavelengths is achieved by heating.
18. The method of claim 16, further comprising
- measuring the chip temperature, and
- using the measured temperature to control the resonant wavelengths to obtain a given time delay of the chip.
19. The method of claim 16, further comprising
- measuring a power of the output beam and using it to control the resonant wavelengths to obtain a given time delay of the chip.
20. The method of claim 16, where controlling is performed in a controller,
- the controller receiving an output of a microwave phase detector, the detector measuring a time delay between an incoming light into the chip and outgoing light from the chip.
Type: Application
Filed: Mar 18, 2014
Publication Date: Aug 2, 2018
Patent Grant number: 10162117
Inventors: Paul A. Morton (West Friendship, MD), Jacob Khurgin (Pikesville, MD)
Application Number: 14/217,663