It is extremely important to keep both the crystal and circuitry in a controlled structure so as to manage temperature sensitivity. This is what denotes a stable temperature, which ought to be higher than the one responsible for exposing OCXO 10MHz Frequency Reference. Better still; the oven can perform better if it is set to turnover resonators degree to give it the capability of balancing with the outside temperature.
Controlling the temperature will enable anomalies which are attached to temperature effects be minimized as much as possible. The anomalies can prove destructive to the resonators and may even allow compensation to a limited allowance. It could be possible to engage top overtone crystals to be used in control of temperatures. Being in controlled conditions make them better.
Stability is highly enabled with these oscillators as compared to the others like TCXO and SPXO which have no temperature control mechanisms. Rather, their temperature characteristics are determined by the crystal units. The oven controlled oscillator is better placed because of its oven block which is capable of maintaining a stable temperature as required.
It is the dynamic and static characteristics that bring about stability. Things like the accuracy of the oven, the resonator and even some other components are responsible for the kind of stability you can get. It is at a certain recommended range that this temperature stability can perform within. The narrow ranges are better placed as it allows restriction to the needed area.
You will however, require more power for this oven controlled oscillator as its consumption is bigger. The insulator you use will however determine the amount of power you will need. If high, then know that the heat usage will be minimal, which creates room for less power use.
The oven temperature ought to be set to some high level than the renowned ambient one to enable the oven to control everything better. This calls for warming of the resonator so as to get the required heat. All these are done so that the oven can be allowed to balance to equilibrium.
Proper regulation should also be carried out so that the voltage supply does not have any variations. If not checked, then disturbances may be noticed within oscillator frequency and this could hinder its performance. Difference in power if realized can cause delay and let the supply go back to equilibrium, leading to wastage of more time.
The oscillator is quite sensitive to load and so you need to engage the functions of an amplifier to give multiple outputs. If built around the oven, then stability of the temperature will not interfere with it. It is better to check out on humidity so that you guard the stability.
Even if this may be the case, instability can be measured and can also be modelled in order to avert these temperature issues. There are also control mechanisms that can be used to control any error and avert instability. Such mechanisms can also help further by giving temperature compensation and effective aging. Additional characteristic series such as retrace can also be considered to avert such situations.
Controlling the temperature will enable anomalies which are attached to temperature effects be minimized as much as possible. The anomalies can prove destructive to the resonators and may even allow compensation to a limited allowance. It could be possible to engage top overtone crystals to be used in control of temperatures. Being in controlled conditions make them better.
Stability is highly enabled with these oscillators as compared to the others like TCXO and SPXO which have no temperature control mechanisms. Rather, their temperature characteristics are determined by the crystal units. The oven controlled oscillator is better placed because of its oven block which is capable of maintaining a stable temperature as required.
It is the dynamic and static characteristics that bring about stability. Things like the accuracy of the oven, the resonator and even some other components are responsible for the kind of stability you can get. It is at a certain recommended range that this temperature stability can perform within. The narrow ranges are better placed as it allows restriction to the needed area.
You will however, require more power for this oven controlled oscillator as its consumption is bigger. The insulator you use will however determine the amount of power you will need. If high, then know that the heat usage will be minimal, which creates room for less power use.
The oven temperature ought to be set to some high level than the renowned ambient one to enable the oven to control everything better. This calls for warming of the resonator so as to get the required heat. All these are done so that the oven can be allowed to balance to equilibrium.
Proper regulation should also be carried out so that the voltage supply does not have any variations. If not checked, then disturbances may be noticed within oscillator frequency and this could hinder its performance. Difference in power if realized can cause delay and let the supply go back to equilibrium, leading to wastage of more time.
The oscillator is quite sensitive to load and so you need to engage the functions of an amplifier to give multiple outputs. If built around the oven, then stability of the temperature will not interfere with it. It is better to check out on humidity so that you guard the stability.
Even if this may be the case, instability can be measured and can also be modelled in order to avert these temperature issues. There are also control mechanisms that can be used to control any error and avert instability. Such mechanisms can also help further by giving temperature compensation and effective aging. Additional characteristic series such as retrace can also be considered to avert such situations.
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