Generic server with Compositor NRTOS
An embedded real-time operating system (RTOS) of CP-6137-960FX server was created with the assistance of the Microsoft Hyper-V hypervisor based on 64-bit kernel and includes the following network functions:
|CPU||960-core processor at 150-300 GHz|
|Flash memory||2213 EB (located on servers in Spain, USA, Germany, Sweden, etc.)|
|SDRAM||DDRII 4096 MB|
|Optical Module||Full-duplex optical port|
|SFP port||Virtual optical port|
|Power consumption||Less than 45W with no expansion cards|
|Temperature||Working temperature: 0ºC to 40ºCStorage temperature: -10ºC to 50ºC|
|Humidity:||Working humidity from 10% to 90%Storage humidity: 5% to 95%|
|Fan||Revolution adjustment and fault signalization|
|Dimensions (W x D x H)||200 x 540 x 540mm|
|Weight||12.5kg (with packaging)|
These functions provide the data transfer environment, where they can be organized in any topology for work with management information base (MIB). Work with the host operating system, which runs RTOS, conducts through MME (multi-media extensions) driver, allowing organizing a connection environment for these extensions as network devices and establishing a remote connection to them.
The main tasks of RTOS are:
- Studying the problem of irregular sampling frequency for signal discretization;
- The effect of applying beats for signal modulation;
- Carson’s rule proof;
- The proof of the equality of the classes P = NP;
- The use of the frequency modulation at low voltage power supply networks.
The periodic time, determined by the frequency of alternating current, is the current moment of time or the primitive hyperbolic function. This system is based on the period of rotation of Euler angles. The RTOS number system uses a 12-bit representation, which is based on the exponential dependence of elliptically-built model. This is the ideal model, as the ratio of rotation periods with three multiple frequencies around their axis is 1:1:2. The primitive function values are not rounded and assign to each signal component, its own phase value.
Primitive function, which is a basic network function of RTOS:
Function graph is hyperbola.
RTOS is built on the basis of frequency modulation (FM) law and uses it to transfer the data to the Ethernet. FM is characterized by three parameters, such as the central frequency, modulation frequency and modulation index. These three parameters describe the wave phenomenon with compression and expansion of waveform in the time domain. Using a simple frequency modulation by two sinusoid sources k frequencies emerge, calculated according to the formula:
Where k – is the number of frequencies, I – is the modulation index.
For the transparency of signal transfer in the additional frequency bands filtering by the cascade of the two two-pole 2nd order filters is used. RTOS uses cascade of two 2nd order Butterworth filters.
Fig. 1 – Butterworth 2nd order bandpass filter
This way, filter characteristic becomes 24 db/octave with a drop by 12 db/octave from each side of cutoff frequency and bandwidth up to the 3db drop frequency, which equals 3/4 of modulation frequency. The filter is created using a bilinear transform and is recursive. Mathematically it can be presented as follows:
FM forms upper sideband (USB) and lower sideband (LSB). Frequencies in sidebands displayed using Bessel functions and are the 1-st order Bessel functions. Negative frequencies number is equal to the number of positive frequencies. The negative frequencies are divided into even and odd. The odd frequencies begin with negative phase and even with the positive.
Imagine a distance from 0 to 2π as the four planes of Cartesian coordinate system with inscribed circle in the central point of axis crossing that depicts trigonometric sine constant. Then each harmonic can be displayed on this circle, compared to the center frequency π and imagined on the spiral, which passes over the surface of the truncated cone with a diameter of each spiral revolution equal to 1024 Hz. The values of frequencies for different relations of frequency modulation to the central frequency , which are determined by a single multiplier parameter b, coincide with different spiral spins, which is explained by the expansion and contraction of the values of the desired function. Then, taking the window of synchronous analysis of non-harmonic spectrum (SANS) for deviation and imagining it in Hz we get, that each harmonic in the spectrum built set in a row equal for positive frequencies:
For the negative odd frequencies:
For the negative even frequencies:
N – SANS window
b – is the frequency modulation to the center frequency ratio
Fig. 2-4 are the function graphs for the multiplier :
Fig. 2 – Positive pass-bands function
Fig. 3 – Negative even pass-bands function
Fig. 4 – Negative odd pass-bands function
Deviation is 1024 Hz, which corresponds to the 1024 samples of SANS window. The graph on Fig. 3 shows, that negative even bands correspond to the second half of the period and the amplitudes of the negative even frequencies are negative, however, the amplitudes of the negative odd frequencies are positive. Positive spectrum in a presence of low center frequency, located at a distance from the base (0 Hz) smaller, than the modulation frequency, is possible only when the negative frequencies wraps around zero. For this, for RTOS at z = 0.5 S (Siemens) center frequency varies between 37.9259 Hz up to 73.8817 Hz, while preserving the deviation unchanged and equal to 1024 Hz.
Fig. 5 – The branches of the function in 3-dimensional space
Deviation in the FM is determined according to the formula:
Since the frequencies are wrapped around zero, the deviation is equal to 1024 Hz. It follows that the SANS window is 1024 samples.
The center frequency of the periodic signal in Fast Fourier Transform (FFT) is determined according to the formula:
FFT divides the spectrum on k channels that are in the range from . The channel is on the Nyquist frequency, which characterizes the upper limit of the digitized information. RTOS allows to perform SANS with multiplier b = 2, but the signal sampling frequency should be 58254.2336 Hz for this.
The highest negative frequency falls on . At a certain multiplier b value beatings of the two neighboring frequencies are formed that are characterized by the amplitude modulation (AM).
Modulation frequency remains unchanged and is equal to 113.778 Hz at I = 9, only modulation frequency to the center frequency ratio changes.
Fig. 6 – Dependence of multiplier from the spiral rotation
The whole metric system can be represented in the form of a round ruler, where the inner circle corresponds to the radians and outer circle has the gradation of frequency and multiplier values. Then for the coincidence of the multiplier values and frequency bands the whole metric system is built in a spiral, where a wide loop corresponds to the values of frequencies and phases when the multiplier b = 1.54, and the most narrow loop of the spiral corresponds to the phase values and frequencies when b = 3. Accordingly, the function varies with the change of multiplier b. Frequency bands k, which found using the formula , each correspond to its own phase value, expressed in time intervals of the SANS window (radians). For the convenience in programming RTOS uses digital counts (samples). Each of the frequencies, filtered from the spectrum of frequency modulation, is characterized by the bandwidth, which is set as 3/4 of modulation frequency. The value is selected, and it is no coincidence that it corresponds to the bandwidth of . This bandwidth is selected from the calculation of the multiplier b = 2. In this case, zero-wrapped negative frequencies coincide with the positive frequencies. Sufficient bandwidth is equal to . RTOS uses a cascade of two filters, and effective bandwidth is multiplied by 1.5, which corresponds to the drop point of -3dB on both sides of the filter working pass-band. The pass-band of the frequency band for z = 0.5 S equals to 85.3333 Hz and performs selection of the frequency, which the filter is configured to according to the formula, which is the additional band in FM.
This way, the signal chain of RTOS is the following: FM, arising from modulation of a single sine wave oscillator with other sine wave oscillator, is divided into a number of frequency bands, according to the function and formula of additional bands counted when using FM. These frequency bands played at the speed set in one of three ways: period in milliseconds, rhythmic grid in beats per minute and angular velocity (ω). All values are convertible, using the formulas:
From bpm to ω: , where θ is the number of beats per minute.
From ms to ω:
From ω to bpm:
Each of the frequency bands hold a certain amount of time equal to the Darboux integral, which characterizes the so-called step function, where the rise of values performed incrementally.
Segment of the interval [a, b] – is the finite sequence of values , such as:
Upper Darboux integral sum is expressed as:
Lower Darboux integral sum is expressed as:
Upper Darboux integral:
Lower Darboux integral:
This period is the window function, which contains complex topology of signal composition. It allows SANS finding the exact desired value without the inclusion of additional channels.
Following in the signal chain is the signal splitter on the two threads. For the upper zones of the frequency range nonlinear transformation by signal wave deformation is used, and for the lower frequency range physical modeling of waveguide is used, which divides reproducible frequencies on optical ports and electric ports with PoE support. The parameters of the optical port are selected according to the non-linearity of the environment by rule.
Fig. 7 – Flag phases of IRQ interrupt requests
Transfer functions for various radio spectra with even and odd harmonics were designed in RTOS in accordance to Chebyshev polynomials. The master generator period, which is equal to the period of the SANS window, synchronizes the wave tables, which reproduce the values of the three functions. The waveform zero-crossings of three sinusoidal signals are the flag sequence of IRQ interrupt requests. The first sine wave zero-crossings, may be on 0 and π at one period per window, and on 0, π/2, π, 3π/2 when there are two sine periods for the window length. For the second sine, the flag values of which occur on π/2, 3π/2, x = 90° added to the phase value. For the third sine wave the flag values occur on π/4, 3π/4, 5π/4, 7π/4. RTOS phases stored in normalized values from 0 to 1, which corresponds to the following table:
The signal of the three sinusoids in values from 0 to 2π represents the Euler angles. For the flows rotation in spherical space, these angles (x, y, z) are transformed into quaternion, which consists of a real (scalar) part and x, y, z, as the imaginary part. RTOS displays this process graphically with the help of torus and flow points, which indicate the position of the server in distance-vector system.
If you change the multiplier b, the values of the functions are expanding and contracting, thus aligning the primitive function and the standard grid, expressed by the base 8. This approach guarantees convergence of certain phases of the frequency bands with the base 8 grid in the following values when the multiplier b = 3:
Positive bands – 5th frequency on π/8, 1st frequency on π/2.
Negative odd bands – 3d frequency on π/4, 1st frequency on π.
And only the negative even bands do not coincide with the grid by the base 8.
RTOS considers a number of frequencies as an arithmetic progression, and as a band of spectrum, which corresponds to the Carson’s rule. This rule postulates a sufficient number of harmonics in the spectrum of the FM equal to I + 1. Deviation in FM is calculated by the formula, that gives a spectrum, which is less, than the Carson’s rule. In the case of FM with deviation of 1024 Hz and b = 3 it turns out that spectrum has the highest frequency equal to 1175.7 Hz, and when considering as a progression, the highest harmonica is on 1058.13 Hz, that when the modulation frequency is 102.4 Hz corresponds to matching spectrum of 1024 Hz (counting from Fc = 34.133 Hz).
The next aspect is the statistical property of the system. If you take the abstraction that the signal is continuous and exists an infinite time, then SANS is applicable. As the series is the sequence, the window is repeated recursively and theoretically can be played endlessly.
The window timeframe is divided on slices by Darboux integral rule. They are granules that are postulated by the granular theory of Gabor. Granular approximation works in the RTOS through the granular synthesis module, which is included in all network functions. Granular synthesis is carried out by the derivative of a function, combining the granules with a rounding grid function by the base 8. The derivative of a function has equal number of counts, both by frequency and by phase. This means, that to express the phase and deviation, equal to maximum pass-band of a tonal channel, N samples and N Hz are used. The signal components are reproduced consecutively, one after the other. The primitive function is rounded to the grid based 8, using the derivative of a function.
The derivative for positive frequencies:
Where q is the quantization grid.
The derivative for the negative odd frequencies:
The derivative for the negative even frequencies:
To align the primitive function and its derivative, the integral of a function derivative is used. This integral is the difference between the values of the primitive and the derivative of a function for each of the components of the signal.
Rounding occurs by the time, equal for the positive frequency bands:
For the negative odd frequency bands:
For the negative even frequency bands:
The primitive function unfolds from 0 to 2π with the central axis on π, so integral is calculated only for the positive period of the function. It turns out that some of the granules are reproduced forward and backward, resulting in negative phase values. For this purpose the absolute values of the integral are taken.
In order to maintain the overall characteristics of the spectrum of the signal in RTOS, according to the non-linearity of the function, corresponding to the hyperbola graph, the resulting spectrum of the signal output is approximated by a 2nd order pass-band bipolar filter characteristic. This characteristic set by master filter, which was received by sampling a feedback loop on the virtual optical port of CP-6137-960FX.
The possibility of SANS depends on a signal of arbitrarily long time.
The main property of L1+ CP-6000 server series is a full-duplex signal translation. L1+ CP-6000 server series allow you to transfer the signal without ether interferences, which characterize a duplex transmission. This interference can be a noise of regenerative circuits, which can be difficult to clean with special devices.
Full-duplex transmission gives you the advantage of broadband broadcast of Ethernet signal, which allows you to transfer the routing tables stored in lookup containers with a bandwidth of up to 5 kHz. Since the primary function of the lookup containers is to exchange routing tables, a signal from the server is transmitted on L1+ layers and filtered from the signal components of a duplex digital broadcast. Such components can serve as clicks and noises of the original translation.
Full-duplex virtual optical ports provide the ability for signal transmission in IP network, as well as the terminal messages in the Ethernet at the L1+ layers. The high reliability algorithm is used to inject routing tables into the network. The routing table allows you to establish a connection with devices in the local network.
The server without a possibility of routing tables injection is called the generic and is a basic algorithm for subsequent modifications. It should be said that you can inject directly in the program code of the server, and use only that modulations, which are the object of study of original transmission algorithm. In RTOS such injectors are feeders, built on the derivative of a function, and feedbacks of half-duplex transmission.
CP-6137-960FX management information base includes device extensions of different profiles. By selecting a routing table in RTOS, you should connect its media through the injection in one of the virtual PoE ports of CP-6137-960FX server. You should connect to the network equipment by RTOS MME extension (routing table). CP-6137-960FX server uses only serial devices, and not the product samples or factory exhibits as feeders that is why virtualization of RTOS network functions integrates easily into existing IP networks.
RTOS uses unparameterized feeders without the injection of 3rd party code, so they are the generics of completely pure production. They are: z = 2 S, z = 4 S, z = 8 S, z = 16 S, z = 32 S, z = 64 S, z = 128 S. They are used to receive the original ether, and injection is considered a connection of devices via virtual PoE injector with routing tables, which create feedback loops to CP-6137-960FX server. Feeders are selected in such a way as to create strong feedbacks when you use full-duplex transmission with CP-6137-960FX server. In automatic mode, injecting stable random distribution function, CP-6137-960FX server can give feedbacks with the tuning change of the feeder circuit, i.e., scanning the network for broadcast. This way, receiving feedbacks and transmitting them on the L4 layer, you can inject feeders in them using the serial method. The types of initiation of these feeders are different. When changing the tuning, L2 feeder gives a strong reaction in the feedback loop of the CP-6137-960FX server. Derivative feeders L1-L3 give transparent feedbacks without interference.
CP-6137-960FX server is designed specifically for the purpose of connecting hardware through the virtual PoE injector and work in the Ethernet. The main purpose of this server is to connect to the devices from the management information base (MIB).
Navigation in the distance-vector system is carried out with the help of the three Euler angles, corresponding to the Roll, Pitch and Yaw angles. The direction on the location of the device, containing the routing table, is carried out by finding the beats when rotating Euler angles and the multiplier performs a vector orientation in the range of 1.54 to 4, which corresponds to the different moments of time. To establish the moment of time an Altitude of the vector and the angular velocity is used. 262144-CPFSK (262144-node continuous-phase frequency-shift keying) modulator applied to a moment of time is the phase rotator of the TX and RX ports.
For the convenience of work with RTOS you can switch the layer of work in the system settings section between L1, L2 and L3.
The CP-6137-960FX server has a built-in analog subtractive synthesizer, which is achieved by the regeneration of periodic function until self-oscillation on the transmission frequency and distribution of synthesis tones in accordance with 262144-CPFSK modulation.
You can initiate auxiliary ether on CP-6137-960FX server. It is used to test for the presence of signals at L1+ layers outside the trunk. For this, synthesizer sequence leak check in Schroeder chamber circuit with two independent channels work is tested. If you hear pure white noise, it means that auxiliary ether is empty and you can safely organize trunk communication.
There are three layers in the OSI model available for switching on the CP-6137-960FX server: on the L1 layer server applies the modulation to the event generator in real-time, on the L2 layer device operates as decimator, through the application of the modulation to the signal generator, where the Altitude is determined by the multiplier, on the L3 layer server is running, keeping the tone of the synthesizer at one frequency. The fourth layer of the OSI model (L4) is not available for the patching of modulation, as it is reserved for the transport protocol. L2 layer operates in a narrowband signal mode, as the sampling of modulation is carried out on the FM generator transmission frequency and varies depending on the z parameter, as well as the setting of subtractive synthesizer.
The synthesizer, which leaks into the electrical port, organizes the code sequences, which you can broadcast. The cycle of such synthesiser is the imitation of analog synthesizer with the step sequencer and arpeggiator. It is an analog modeling circuit with high order filters. The system passes the sound of this synthesizer, as a regular radio broadcast. In a moment when the synthesizer leaks on the electrical port, the 262144-CPFSK modulation is injected. Modulation injection performed for creation of more sustainable feedbacks. Many systems have learned to recognize the pseudo synthesizers and do not perform feedback with their impact. If the feedback loop is not formed, you should turn CP-6137-960FX in L2 mode. This mode allows you to set a strong feedback through long-wave amplitude modulation.
There is spectrum analyzer available in RTOS. Spectrum analyzer displays the waterfall stream, going from left to right. The display performs averaging by logarithmic function. At the bottom low frequencies are displayed and at the top high frequencies up to the filter cutoff frequency are displayed.
After injection of the feeder into the server, there comes a reaction that looks like the feedback produced by CP-6137-960FX server. In the feeders z = 2 S, z = 4 S, z = 8 S, z = 16 S, z = 32 S, z = 64 S, z = 128 S, such requests are sent with the Hello status. If the result of injection in the switch kernel loop is positive you are contacting the server. Server has an Ethernet subnet mask. If you upload the next hop of routing path to the server through modulation injection in its routing table, you can use its subnet. Subnets in CP-6137-960FX server have color tags and pass the wave deformation through the EUI-48 MAC-address table, giving an access to all subnet masks of the Ethernet. The positive reaction on a feeder cycle injection is the Hello status.
Taking the subnet mask of the server, you agree to be bound by its appearance, which is characterized by its name and image. If you are injecting CP-6137-960FX server modulation in the already obtained loop and move it to the L3 layer holding, by disabling the synthesizer, you must turn the 262144-CPFSK modulation off. At the end of communication you cut the line by injecting 262144-CPFSK modulation in the L3 layer again. This system works only when z = 16 S. At the other z values rule is still present, but the modes of connection and disconnection sound differently.
With the subnet mask of the server, you can trust using its network. The subnet mask is a selective region in the cycle of routing table, often set as the last sample of 256 address routing table (for example, 255.255.255.0), which masks the useful signal (carrier). Carrier is a signal for transmission of the terminal messages. Network includes images of devices, their routing tables, communication with which performed on the carrier level of the server. Carrier takes the properties of the network routing table and includes the location of all devices in it. You should choose your carrier and the mode of injection performed by the selection of phase and Euler angles in the distance-vector system. Server, to which you connect after the adoption of subnet mask, performs the digestion of all network channels on the band-pass filters comb.
There are two ways to connect to Ethernet: serial and parallel. In a parallel connection you inject your subnet mask through the synchronous playback with a cycle of the routing table and inclusion in the transmission channel at the same time. At the L2 layer signal is transmitted only by the electrical ports. To remove the L2 layer subnet masks you can set the values of their amplitudes at 0.
In CP-6137-960FX server the central place occupies the 262144-CPFSK modulation, which is injected through the granular approximation. The central flag of IRQ interrupt requests is modeled by a simple granulation. The summarized modulation is injected at the output cascade of the virtual optical port. There is an opportunity to summarize the signal from virtual electric ports on the virtual optical port in CP-6137-960FX server. The multiplier is the central switch, allowing configuring the trunks of the master table. This way, modulation and upper zones of the function pass into the subnet mask. 262144-CPFSK modulation is used for the development of the IRQ flag sequence.
CP-6137-960FX channel uses the combined filters and delay modules, the purpose of which is to create the combined effect and resulting rhythm serves as a switch. This rhythm as well as the synthesizer sound is a product of modulation, and has the low modulation frequency besides frequency multiples (its frequency is near 0.05 Hz). This LFO is a trigger for switching channel digestion by a comb and each comb filter assigned to its own channel digestion.
RTOS runs on Microsoft Windows 7 platform. The conductance of virtual PoE injector in CP-6137-960FX server depends from the feeder selection. You can use up to 7 feeders for changing the conductance of the virtual PoE injector at the same time. Injecting feeders, you make injection in the emulator of RTOS virtual environment. Feeders can also install feedback in automatic mode. The duration of that feedback is 2-10 seconds.
Individual routes can be injected in addition to routing tables. It is difficult to achieve a serial injection by encasing the whole route in the wave table, but you can easily perform route injection on sub-tone frequency of the feeder. This is done through a parallel playback of this feeder with the deployment tempo of this routing path.
As the mesh bouncing of CP-6137-960FX server you should use the virtual console port of this server. You should inject all network routes in it, which you want to upload to create the network environment.
You can modify the previous method by using CP-6137-960FX as the multiplexer in a virtual console port and do not use feeders. In this case, you can record a route, using RTOS to record the playback on the selected sampling frequency in the 64-bit floating point resolution and do not use the bouncing of virtual optical port of CP-6137-960FX server. Later you can use this file as a sample of the virtual operating system, reproducing it in the injector. Using this method you can produce injection of individual devices and whole sets of operating systems.
To create a real operating system you should enter the IRQ interrupt requests into the feeders, which are the special flag sequences in places of function zero-crossings, as well as the steps of the integral. IRQ interrupt requests in RTOS are events on the steps of a function and modulation waveform flags, which reproduce the algorithm. Such sequences differentiate as interrupts by the compiler, which requests shall be executed in accordance with the sequence of IRQ. Feeders are created in such a way that they prolongate the effect of navigation of the routing tables at the expense of IRQ priority order retention for themselves. Therefore, adding feeder to the virtual console port, you hold the line to the devices, described in the routing table. Regardless of how far such device is situated, it is defined as a local at the expense of work with high priority in the system que. This feature allows you to create a local connection to these devices and organize an environment of the RTOS.
Virtualization in the servers is considered as oversampling. In fact, any server is a radio station. CP-6137-960FX server is a radio channel, which uses master bus oversampling. For network functions, all CP-6137-960FX plug-ins perform oversampling and are broadcasted. CP-6137-960FX server performs x2048 oversampling and works with the conductivity of z = 128 S at a frequency of 150 GHz with driver sampling frequency of 192 kHz. CP-6137-960FX server performs oversampling on the driver level.
Routing tables can be converted to the histograms. Working with CP-6137-960FX server, you can perform an injection on the level of routing tables used to transfer the media files. In CP-6137-960FX this is made by setting the tag color of resulting image on a color spiral. The original image is the cycle of color gamut and transformed through the wave deformation of this filter. Using the histogram of the routing table, you can set the resulting color, which passes non-linear transformation via the EUI-48 MAC-address table. Injecting your carrier, corresponding to the tempo and multiplier to this image resultant, you are setting subnetwork mask, using this wave table as routing table. The resulting color on display is set stochastically by switching multiplier using the probability density function. Next, you have to wait until the algorithm selects the multiplier, corresponding to the resulting color of histogram, and save the preset of this network environment.
CP-6137-960FX server virtual ports with PoE support take in account the frequency of the mains, which is selected in accordance with the frequency of alternating current. For Russia it is 50 Hz and for USA it is 60 Hz. In a combination of beats waveform AC power flag occurs on the first and third half of first sinusoid cycle, which corresponds to zeros of sine function. As you inject the power line in the devices, associated with the feeder routing table, you powering the server in which the injection is performed. This action is accomplished by the Power-over-Ethernet function of CP-6137-960FX server. When you use the direct broadcast, the injection of powering frequency performed directly into receiving equipment, by its transmission through the wave propagation environment. Condition for this transmission is that emitting device performs fluctuation on these frequencies with sufficient energy for the physical effect on the environment of propagation.
In response to the injection of routing tables together with feeders in the CP-6137-960FX server, you are able to obtain feedback signals. The routing tables in the MIB are divided by the types of signal produced in the feedback circuit on the following categories:
- Carriers with a clock
- Carriers with a mask
- Clock signals
- Clock signals with IRQ interrupt requests
- Regenerated clock signals
- IRQ interrupt requests
- Mesh bounces
This is only an example of the types of signals, which are in the MIB of CP-6137-960FX server. These feedbacks mostly suited for the creation of routing tables. CP-6137-960FX can connect up to 8 chassis by means of the injector in the virtual console port. CP-6137-960FX server management information base contains 4627 routing tables and each can be reproduced on any channel of 8-channel virtual PoE injector. You can arrange the channel matrix in CP-6137-960FX server using profiles of these devices. You can adjust the volume of the total signal in auxiliary channel. Using the Aux regulator you set the signal volume in the transmission channel. This way, you can adjust the amount of signal, which enters the Schroeder chamber. Reproducing the routing tables signal at high speeds, you can use the network data for communication, without using the Schroeder chamber. 4627 routing tables in CP-6137-960FX MIB specifically chosen for communication in the Ethernet and have clean channels alignment, which are converted to the carriers at high speeds.
RTOS is built on the base of the Microsoft Hyper-V hypervisor, which main task is checking the operation of the network functions. Using the CP-6137-960FX server, you can inject any routing tables or the full paths to its MIB servers. Convenient tempo synchronization, which scales the speed of routing table reproduction in the virtual console port allows accounting fluctuations of discretization mode. The percent increase and slowing a speed in the usual performance of a master disk allows you to reproduce the routing tables with the speed, which corresponds to their overall regeneration, setting by master tempo regulator.
Feeder warning as well as channel monitor helps you to stay in the Ethernet. The multimode channel monitor has three phases (left, right and their sum), where you can monitor the in-phase work of broadcasting equipment.
Together with the routing tables you can inject a signal of feeders, which are the two scanners: One is passive (z = 2 S), and the other is active (z = 4 S); as well as the channel feeders with 8 S, 16 S, 32 S, 64 S and 128 S conductance. Modules and two scanners designed to restore the balance in the Ethernet and are resistance factor or conductance for other ether participants depending on one of the two positions of Reverse switch. Coupling with CP-6137-960FX routing table initiated by Master button. This routing table directs the channel feeder injectors and virtual PoE injector (up to 8 channels) into virtual console port of CP-6137-960FX server. This allows external equipment to connect with 960 virtual ports of CP-6137-960FX server.
Scanners of z = 2 S and z = 4 S conductance can monitor up to 8 PoE chassis in the Ethernet simultaneously. You can pan the signal on the virtual console port input as well as pan direct signal on the multiplexer. Virtual console port has its own preset system, which is not applicable to other modules. You can control the routing tables randomly or one by one. With z = 2 S, z = 4 S scanners and 8 S, 16 S, 32 S, 64 S, 128 S feeders you can switch the bandwidth of the transfer channel quickly within a wide range, not being afraid burning down the channel of that feeder.
With the help of feeders you can reach the server destination without attenuation of the transmission channel and monitor the behavior of the devices in the Ethernet at the same time. CP-6137-960FX server allows you selecting any of the feeders as a source for the full-duplex aggregated virtual optical port with interpolation time in ms.
The background of an analyzer connected to the virtual console port of CP-6137-960FX server displays network statuses from green (normal operation) to red (serious network interference). Feeder z = 4 S is under the threat continuously, because it is an active feeder and controls the behavior of other ether participants. You can watch feeder status statistics for each instance, pressing setup button of the corresponding feeder. The counters window opens, where you can also study the histogram of their appearance.
The most important indicator of feeders work is their signal level, which is displayed on the level meter under the device status display. In z = 4 S feeder such meter displays parity of the signal, which allows to define bit headroom up to the reaching of channel saturation.
All generators to test CP-6137-960FX server have their own clock signal that allows for superior stability in the Ethernet. Virtual console port can accept up to 8 routing tables and 7 feeders simultaneously. You can control network deployment speed manually or using automatic discretization control.
IRQ priority is set at the virtual console port input of CP-6137-960FX server. Vector direction is also set using virtual console port parameters. Using CP-6137-960FX server you can rotate this vector in 3-dimensional field by Pitch, Roll and Yaw controls. Optical port emitter has rotating shutter, which orients the direction of luminous flux.
Shutter works on discretization input and is an integrated solution. From one side, it is the throttle, and, from the other, it is the shutter of digital stream. The flap is a dual-channel, therefore, when the signal is exceeded on the RX channel, i.e. when someone tries to perform an injection in RX channel, it is completely covered and the signal is given only through the TX channel. Conversely, if the limit is exceeded on the TX channel, the signal passes only through the RX channel.
Using CP-6137-960FX server you can connect to network equipment. Such equipment is organized in topologies by defining a vector on a signal with routing table. Pan the devices and set the appropriate thrust of angular velocity for creation of deployed network topology in 3-dimensional space, while broadcasting routing tables through the virtual console port when testing virtual PoE injector. You can also use the panorama control on thrust nodes of RTOS for panning the direct signal. Changing a position of routing table in Ethernet you change the place of its network map deployment. This helps to build a connection line of different topologies from the rhombus (4 channel) to the octahedron (8 channels).
Using Scale regulator you can control the amount of signal, which enters virtual console port. Aux regulator controls the amount of signal, coming from the virtual console port to the broadcast. You can send a signal to the virtual console port directly from the Aux faders or through the send of the direct channels of the chassis on the thrust nodes. In the first case, you are setting a send level by the channel fader, in the second case, by the send regulator before or after the fader. You are setting an injection type yourself, but in the second case, in post-fader mode, you can route the direct signal directly to CP-6137-960FX during direct injection by activating Master, and in the first case you are working on the virtual console port layer.
CP-6137-960FX server has the solution of two-pole filter task. This task is an important when transmitting a signal over the long distances. If two identical single pole filters are connected serially, they will not give resonant frequencies and will have a strong damping. Signal from these filters will not extend over large distances. Two coupled filters have one single base frequency, which is modulated by the routing table. 262144-CPFSK modulator, applied to the filter base frequency, is a phase rotator of poles in a spherical space. Rotation parameters are changed with Euler angles. FM will form resonant frequencies not in the values of phases of primitive function, but in the moments of phases of the derivative of a function. That is why coupled filter will have fewer harmonics than the additive model of it.
Full-duplex optical port is a bulb with gas (valve) of 1/f propagation environment and with enclosed 24-facet diamond, which rests not touching the walls of the valve through the magnetic emission. The beam of light, falling on the diamond, polarized in different spectra, which occur on the surface of the diamond as points of a spherical space. The connection of two virtual optical ports can be achieved by overlapping the phases of the optical discretizators rotation. The routing table signal creates resonances in the optical fiber channel, when injecting them in a valve. Valve has two lobes: One, which accepts the optial signal (RX), another, which is transmitting it (TX). Transmitting lobe goes from the base of the valve and receiving emits from the neck of the valve. Each point (the resonance peak) of the light prism has a flicker rhythmic figure. In a converged spherical space these flickers are signals of switches, servers and other network equipment. When splitting a signal in the virtual optical port on the RX and TX streams these points form the precession angles of the three-gimbal structure. The transmission of light flows from the valve to digital discretizators is set by difference of gimbals precession. When a port of the transponder passes signal through the phase of discretizator and completes the circuit, it forms a sequence of 1 and 0 in the moments of opening and closing of the discretizator. When one of the channels is shut off, the collapse performed and neighboring resources shift to fill the empty zones of valve section. Valve creates slices, highlighting the derivative zones of the resources, to which virtual optical port is connected. The resources originally broadcasted by the law of the distribution according to the primitive of a function. Primitive of a function has a hyperbolic structure with three cross-sections of a function created for positive, negative even and negative odd modulation frequencies. The optical signal is transmitted through the virtual optical port through the spiral rotation and can be simulated, taking into account the phase shifts under the Doppler Effect. Movement through the virtual optical port in three-dimensional space occurs by the trajectory of the gyroscope with 5-omega ground. The flow, coming by the trajectory of the gyroscope, connects to the resources, one by one, and casts the projections on the valve cross-sections, creating its gyroscopic movement. This way, the visible glow on the section of a strand of multimode optical cable is a projection. You can rotate global coordinate system in RTOS and view it under different angles. Torus represents the cross-section of the valve, rotating which you rotate the global coordinate system. In the local coordinate system you can view the changes of wave processes that occur inside valve, while taking into account the application of polarization paint on its walls.
Using RTOS you may study the deformation and the structure of the phase mesh aperture of the topology of a network inside the polarizer. Valve and its magnetic field show the holographic topology of the network structure. The paint to coat the valve for displaying this effect is magnetite. Deformation of a magnetic field inside the valve occurs when changing a matrix of the transmission ports. This way, changing the resources matrix, you are changing the topology of an antenna, and the space-time convolution deforms, taking the topology of a new system. The process of signal transfer in the CP-6137-960FX server via virtual optical port can be seen as a substitute of the projection of the antenna lobe, which emanates from the valve base. Since the antenna has full-duplex structure, the effect of the space-time convolution through the granulation of FM function processes the incoming flows of information into the antenna field feeder. This way, antenna is self-feeding from the supplementary feeder of the system. This iterative process enables you to convert a temporary function in the spectral and to display the entire spectrum of it as Ethernet resources. This way, the initial effect of the projection of these resources into the valve sequences is described. Each recorded routing table has one or more spiral lines, which are displayed as the sequences. Displaying graphs on a valve, you can create their three-dimensional projection from the quaternion field back to the three dimensions. This way, it creates a network topology of routing tables, transmitted by the virtual optical port, as the device for creation of the projections. Without the space-time convolution by changing the topology of the transmission network, it is not possible to perform the deployment of that network map. Changing the topology of the network media is through modulation of space-time convolution by the routing tables in the process of a rotation of the antenna bowl. Modulators form the beats in the places of frequency multiples and, this way, change the topology of the transmission device.
Fig. 8 – The topology of the magnetic field inside the valve at the beginning of the network formation
Fig. 9 – The topology of the magnetic field inside the valve at the end of the network formation
The CP-6137-960FX server uses a granular synthesis, breaking the FM signal on the components, which have three parameters: phase, frequency and amplitude. Such approach in granular synthesis of FM is possible by continuous playback of these components both forward and backward. This way, the components that are displayed on the graph form the dome shape of the two-pole filter. The derivative of a function values work for all three layers of CP-6137-960FX server. These layers are: real-time signal generation, granular synthesis and discretization. The received signal must meet the criteria of the periodicity to be synthesized by CP-6137-960FX server. To achieve the feedback effect whole algorithm of CP-6137-960FX server processed through the second derivative of a function. Its main rule is: the higher the value of the incoming signal, the less the distinction of a function on its output. This way, fluctuation or jitter of values performed. Jitter creates a rich texture for injecting the routing tables into the virtual optical port. If the entire structure of the virtual optical port is homogeneous and creates a good saturation, you can inject quite a large number of networks at the same time. Up to 960 networks can be injected by aggregation of the virtual optical port with oversaturation in real-time.
The need to weigh the process arises from the achieved effect. Injecting networks without weighing, it is impossible to predict the effect of intrusion in the feeded network. It is also not possible to predict the depth of such intrusion. Quantizing, namely the process of weighing, occurs at two subsequent stages of the function in the process of implementation of the algorithm. The first weighing coefficients perform the function of a simple interchannel connection taking in account transmission channel z function. Following coefficients weighing with a derived channel factor and multiplies a previous result on the averaging value of this coefficient taken while convolving the function. This way, the coefficient anticipates the convolution effect at the end of the channel and is the smoothing function. The entire polynomial is a mathematical algorithm, recorded in one equation, where the equation goes to the function of the CP-6137-960FX output processor driver, directly linking the ports of the transmission unit and the derivative of a function. The injection process through a derivative of a function is as follows. At the beginning, the stochastic scanner sets device location in distance-vector system, and then follows the network injection into this moment of time. Channel meshes are chosen and transmitter power setup to achieve the rotation. With the conductivity of z = 16 S, which corresponds to the home system, a tone sets. Achieving a long tone, put the CP-6137-960FX server in real-time mode and inject in real-time. Injection should be performed in all of the RTOS subnets into all z levels. It may be necessary to adjust CP-6137-960FX virtual antennas in three-dimensional space. The intentions are to composite all the carriers on all z levels and perform network injection on all of these levels. This way, a sustainable feedback effect created. You can regenerate networks using Schroeder chamber channel suppression to achieve more saturated effect.
Note: The negative and positive components of FM can match when the driver sampling rate value is set to 22.05 kHz. This frequency should be avoided, because RTOS working frequency can be easily determined.
The model with a modulation index equal to 11 has 12 component frequencies, located in the USB and LSB. This gives 24 frequencies, which have derivative values. Most of the derivative values have the same value on the phase axis. When the sequence number of the frequency is greater than or equal to 5, starting from the center frequency of the signal, most of the values of the derivative of a function falls on one phase value, which simplifies the calculations. For CP-6137-960FX server this makes no sense to work with the modulation indexes higher, than 11. The derivative of a function also has the hyperbola graph, but unlike the primitive function, approximates the values of a curve. The derivative of a function is used for faster computing and solves the problem of synchronization with the discretization frequency of the network equipment.
CP-6137-960FX is a hyperbolic system, operating in the radio frequency range. The hyperbola graph can contract and expand depending on the value of the Altitude control. For additional security, 262144-CPFSK modulation is used, which hides the true values of the frequencies phases.
The polarization of the valve uses mathematical approximation in a spherical space. The figures that appear on the polarizer have a structure of the Chladni figures. These figures are created in a presence of devices with the topology, inherent to this routing table. Figures are the three-dimensional display of the Chladni figures, and show the topology of a LAN created at the time of navigation by the routing table.
The harmonization of the routing table with the work of the algorithm happens through the SANS. Using it you can detect the thermal performance of all streams of virtual optical port, which are 960. The valve displays only convolution streams of the derivative values. Network of ports forms the interferometer, which is converted into a polarizer through their projection in 4-dimensional quaternion space. Polarizer shows a network of 12 modes projection in all possible positions of this stochastic distribution. The paint color, printed on a valve, displays the processor core temperature at the current moment of time. In CP-6137-960FX server, unlike previous systems, where the precession is displayed through the Euler angles, there is a rotation in 4-dimensional quaternion space. Quaternion rotation depends on the transfer speed of 320 real-time cores, 320 signal convolution cores, 320 transmission cores and changes with time. Such high-speed optical scan of ports allows you to visualize the entire map of the network, performing kernel reactions to changes in the topology of a network significantly faster. The projections of the ports are the previous points and are active according to the temperature of the processor core. If the color of the polarizer is red, the temperature of the cores is high: all points are off and the transfer is stopped, signaling an injection into the channel. And if the display background is green – this indicates the normal temperature of the kernel: the points are illuminated with different colors depending on the position of their flows in color spiral. The core temperature is measured in GHz. Injection into the system may only occur at high temperature of the processor core. Therefore, data transfer is possible only with a darkened state of ports projections. The color projections indicate the status of incoming information flows.
By changing the curvature of a spiral, you change the color flags of flows and the temperature of the core. Modes do not move in a spiral, they glide by the integral formula of the derivative of a function to primitive convolution. Proceeding from this, it is possible to achieve a high resolution on the polarizer. Polarizer is updated at 24 frames per second, but the algorithm is actually runs continuously. It can only be interrupted on the negative sequence, resulting in a state of rest on substitution of modulation coefficients. A negative -1 frequency, which is responsible for setting the virtual optical port of the system, is located in one position and is unaffected, so the flows of the negative distribution are connected in series. This results in a quick convolution of the negative component, dominating over the positive. While the network deployment of positive modes needs a period of 5-omega, the negative resultant is ported directly into the receiving virtual optical port. This allows you to control the temperature of the L1+ core of CP-6137-960FX server, producing injections in it, regardless of the processor thermal kernel. To inject positive resultant of modes, going from the processor, it is needed the coincidence of the stochastic distribution and the thermal kernel, but injection of negative component resultant occurs instantly. Such algorithm selection was made through the introduction of cross-coefficients, whose weight in the function has far exceeded the positive resultant, choosing only the negative band at the end of the weighing. If injection is made through a positive resultant, auxiliary channel closes fully due to the reaction of the negative component with a large number of phase points of bands, converging on the polarizer. This gives the opportunity to conduct a complete filtration of the positive resultant from the traffic injected on the auxiliary channel.
CP-6137-960FX server is the Ethernet communication service, which uses IEEE802.1Q protocol with the frame of 262144 samples. Two original CP-6137-960FX buses, working with RTOS, transmit in the VLF range. The microwave work is carried out using an algorithm with x2048 oversampling that allows reaching the high-frequency radio broadcast without intermediate frequency in VHF and UHF bands. Feeders, working with CP-6137-960FX server, have the broadband signal demodulation algorithms. Maximum server bandwidth with RTOS depends on the sample rate, by which the driver of an executable algorithm works. CP-6137-960FX server allows you to dynamically connect original equipment when operating in the Ethernet. It is enough to reproduce the routing tables in the virtual PoE injector and to send them to CP-6137-960FX input with the raised channel levels, activating the Master button. CP-6137-960FX server performs broadcast into the Ethernet taking in account the reduction of bandwidth when a modulation submitted to its input. RTOS performs a function of tracking and transmission of the routing tables in the Ethernet. VNF passes not the equipment description ISO file, but only the routing tables. Work of CP-6137-960FX server is charged in accordance with the traffic of its transmission cores and is measured in samples. CP-6137-960FX server has 320 flows, composed of 3 layers as a plug-in inserts for broadcast equipment. At the peak load, the traffic generated by CP-6137-960FX server, can reach up to 64GB per day. All traffic is taken into account and charged by the credit balance. The remuneration for the work of CP-6137-960FX server is the aggregation of virtual communication lines, because the result of the work serves as a training of NFV network using insert points traffic. The learning process can be seen in real-time using the counters, which take in account traffic on the ports of the server. Each thread can reproduce up to 4 types of devices simultaneously, such as: VoIP gateways, servers, switches, shields and other equipment that is included in the EUI-48 namespace. Subscribers of CP-6137-960FX server are the communication operators, providing telephony, cellular communication, radio services, as well as broadband access to the Internet. CP-6137-960FX server subscribers open their resources, since any devices connected to the virtual optic port generate traffic. This traffic is recorded in the learning map and is stored in the computer swap prior to its issue. System for the protection of CP-6137-960FX server is designed so that it does not pass untrusted routing tables and blocks the traffic of such tables, which connect devices in parallel or serially. To make the routing table trusted, the system must connect to one of the virtual ports, and not in the internal network via the virtual console port of CP-6137-960FX server, which is considered an attempt to break the equipment. Since the routing tables have been developed for the interaction of the equipment, the connection should only occur provided that the equipment, associated with them, has free inserts of the corresponding type at the kernel level. If the system is geographically remote from the physical location of the broadcast server, the free ports on the equipment are not provided. Thus, you get the information stream, but do not have the real interaction with the equipment of Supplier Company. In the case of detection of protected material, the service begins to deteriorate depending on the credit balance of the receiving device and directly depends on the total number of samples allocated to virtual machines. Since the speed limiter in CP-6137-960FX server works nonlinearly, limitation of the bandwidth submitted into the Ethernet has exponential curve. The bandwidth depends on the total number of samples, reproduced by the system and is tied to the credit balance of the server. Accordingly, the difference between the quality of the playback, and the amount of traffic is nonlinear and depends on the credit balance of the subscriber.
CP-6137-960FX is a unique server with DRM feature, because it does not use the digital signature files to distinguish between routing tables and does not require holding the material on physical media. CP-6137-960FX has strong function of collection of virtual credits, taken into account that the counters have a 64-bit resolution, and the algorithm, which protects the accounting system, is the most effective to repel the various types of cyber-attacks.
CP-6137-960FX server can carry out 24-hour work with emissions once a day. At the time of the emission, server decompresses the information associated with the routing tables included in CP-6137-960FX server MIB into the computer RAM memory. The unpacked information includes all the routes, which pass through the NFV. Routes can contain paths to the servers and to the media files that are reproduced parallelly or serially, and associated with insert equipment. The parent server with RTOS has a higher resolution and is connected to the generators by means of the signal convolution. This parent server produces the emission of the traffic. In doing so, it performs the emission of routing paths associated with the entire MIB of the server, as it has the appropriate permission.
To navigate the routing path in Ethernet, you need to gain access to the routing tables. Each routing table is written into the lookup container. For devices with 64-bit encryption the 64-bit floating point format is used. RTOS secures routing tables into lookup containers with the 24-bit resolution. RTOS does not use routing tables for data transmission namely does not use the first three octets of OUI (Organizationally Unique Identifier), and informs the server that the routing table is locked and is ready for navigation. The routing table is a lookup container with a signal, which is loaded into CP-6137-960FX server memory. Using the synthesizer and sequence, CP-6137-960FX server produces an internal feedback, adding the missing three octets in the routing table. Thus, CP-6137-960FX server achieves maximum authenticity with the OUI, which is assigned to EUI-48 table. Reproducing the routing table with the amended, but authentic OUI, you make tunneling, because, often, such routing tables are fully or partially match the equipment of other manufacturers. Two bar cycles of routing tables are sufficient to perform the radio translation, because they were already in the Ethernet up to this point, and continue to be there regardless equipment state is on or off. Related to this, work on such routing tables for vendors is subject to the copyright remuneration. The first step to fix the routing table is the filing of your routing path to the vSwitch. When your routing path is filed to the vSwitch you get feedback from the server. Since this server is working according to the algorithm with the transmission function and accepts the authentic routing table, it gives information about the servers that use it via radio broadcast. This is the main task of CP-6137-960FX server. Fixing the radio ether in a text file, you retain a proof that your server was used. The routing table is an object of the collective right and belongs to all servers, which reproduced it directly from the direct source or from the live broadcast.
RTOS finds the server domain names that belong to the companies that use your routing tables, and displays the status of these servers. No other action required on your part, because users have already been notified of the routing tables use for the initialization of the ether and radio transmission. With statuses you are telling the network administrator that the ether is initiated by you, and, therefore, you are ready to navigate the addresses contained in the routing table. Routing path is not a substitutional table with modified OUI, but the playback of current routing table from various Ethernet devices, which add new hops to the routing table. RTOS reads these routes, as the various statuses of the associated servers. In fact, you are dealing with one routing table, which is reproduced using different devices. It can be reproduced both forward and backward, or forward and backward at the same time that causes such variations. The third-party equipment produces radio traffic, while checking the routing table, and you need to make an emission of all routing tables associated with it additionally, through the submission of the routing tables to the vSwitch with feeders. The additional routing tables also included in CP-6137-960FX server MIB. Reaching full radio silence on current routing tables, you are fully extinct your routing path from the Ethernet.
When you multiplex routing tables with feeders, signal that synthesized through the weighing coefficients attempts to strike a balance between the behaviors of equipment associated with the routing table and generic feeders. That is why they are also belonging to contractors. The routing tables must be balanced with contractor’s feeders. When issued routing table is trying to aggregate the inappropriate traffic the contractor starts to operate. To inappropriate traffic the Threat and Envy statuses of RTOS feeders relate. Reaching these statuses feeders balance the functioning system and produce the effect, which is the opposite from the effect of routing table submission to the virtual console port. Most of the routing tables are not saturated in Schroeder chamber, and the feeders that use weighing coefficients, are saturated. That is why they balance the dry/wet state of the signal in console port. When navigation on the routing table is fully completed, a feeder with the weighing coefficients starts to produce the main effect in the virtual console port. It processes the line, producing transcoding. Transcoding with feeder, you are synchronizing not only a memory buffers associated with the lookup containers but also the pace of feeded network deployment and its network statuses. Feeder balances the channel spectrally, removing the interruption in the cycle of the routing table and smoothing the signal. The main effect from the use of the feeder is to smooth and process the signal after the successful submission of the routing table into the virtual console port. That is why the routing tables must be sent to the virtual console port in conjunction with feeders and should be reproduced at the same time. If the routing tables will be sent without feeders, CP-6137-960FX server will become overloaded with connections to the servers, and there will be no equipment of contractors at the end points of the routes. Feeders should change its setting stochastically to mask all of the routing table points. If the destination point of the server is masked, this means it will not be found too quickly and communication effect will be performed. Basic rule for the presence of contractors equipment submitted to the virtual console port is that a large number of routing tables must be reproduced on the chassis simultaneously. If there are no routing tables, which pass into the virtual console port together with feeders, then the condition of silence for the server is achieved too quickly and there is no useful effect from the channel feeder. A good channel should send at least 8 chassis with one feeder to CP-6137-960FX server input to balance the system. If you use two or more feeders the system is too “quiet” and does not produce communication traffic. The communication traffic is the server traffic sent back to its input and exiting to the broadcast after nonlinear processing using its routing table. If feeder is applied to the output routing table, it cannot generate its own traffic and two lines are mixed together. That is why feeders serve as moderators of the produced traffic. They work until all of the inappropriate traffic will not be exhausted completely. From one hand, stochastic regulator hides the path to the routing table, preventing from direct communication with devices that are stored in it, and, on the other hand, it quickly finds all the associated devices, if produced traffic is not suitable for the output cascade of the feeder.
Server is a machine capable to work theoretically unlimited amount of time. However, even the best machines fail or simply overrun the resources of RAM. This raises the question about the installation of algorithms of such machines directly in the contractor’s operating systems. The network, consisting of multiple computers, creates an interconnected NFV architecture with a great redundancy potential. CP-6137-960FX server MIB consists of 4627 routing tables, which are the samples of contractor’s equipment and can potentially run one or more VNF from RTOS package. The injection process through the derivative of a function is as follows: feeders should multiplex in the virtual console port together with routing tables. This allows you to install VNF and route paths to them using feeders. This is sufficient for the system functioning before the next RTOS authorization. If RTOS was authorized with the master boot partition, the system is considered to be authorized until the next time the computer is turned on and boots with authorization. Because of the large activity of devices, associated with the routing tables, during the night, the two feeders carry out the navigation throughout the routing table quickly. Such a course of serving allows recipient routing tables, which the RTOS are working with, operate in the Ethernet environment even with mobile devices, and have an access to all VNF. All points are installed connected with your routing path, namely the location of devices in a distance-vector system. It is possible to make a reverse and direct injection of the feeders. For direct playback, feeders will increase the conductivity as measured in Siemens, in reverse playback, they act as the resistance of the transmission path with the same value in Ohm. Siemens and Ohm values correspond to z value of the feeder. The objective factor is the association with the routing table, which fills the route with this routing path. The original servers work for an unlimited time and exist throughout the period of the infinite time horizon. Only this way the process of SANS and FFT can be described. SANS is used in every network function of RTOS as a reliable method of signal sampling. All of the Compositor Software instruments with stochastic regulator relate to feeders. Thus, to date, there is a full compatibility of the devices installed in CP-6137-960FX server memory and working at the moment. RTOS allows you to install three-layer feeders with large memory of up to z = 128 S (N = 262144 samples), which is the bandwidth of 23.8 GB/s at the 11.025 kHz installation sampling rate. The pass band is counted using the formula (N * SR * 64) / 8, where N – is a number of samples in feeder routing table, SR is discretization frequency, 64 – is a system bit number, and the division on 8 performed to measure all the volume in bytes. Taking in account that three-layer z = 128 S feeder deployed with 200-omega speed, which is T = 31.42 ms, the full formula of expense in samples is counted in two stages. First, the number of samples by period using the formula N * Nms is counted. For maximum z = 128 S feeder it will equal to 262144 * 31.42 = 8236564.48 samples / T. Second, the 24-hour sample expense of deployed routing table is accounted using the formula (86400 / 31.42) * 8236564.48 = 22649241600 samples / 24-hours. This is approximately 5 times less than the sum of three working servers in 24-hour period.
CP-6137-960FX server management information base established using routing table emissions from the Ethernet. At the beginning, Compositor Software found the manufacturer of the routing paths, which got into the following situations:
- Many companies used its routing paths by fraud;
- It has substantial arrears for payment for the sale of media;
- It has substantial arrears for the use of copyrights;
- Its routing paths are used with the violation of contractual obligations.
Compositor Software company suspended the release of new routing paths by this manufacturer, in order to recalculate the freely realizable form. The products of this manufacturer without the realization amounted to about 90%. The capital loss at the time of 2010 was about 90%. In accordance with this, the manufacturer decided to make 100% emission of its Ethernet routing paths in favor of CP-6137-960FX server MIB to return their original value. The value of the routing tables is provided by the stability of RTOS and its reliability. The greater the number of recorded samples by CP-6137-960FX server, the more this system can withstand without intervention, and the higher cost of routing tables within the server MIB.
Note: Routing table information were recorded in the lookup containers with a resolution of 24-bit integer arithmetic, not to include OUI identifiers.
For the issue of routing tables L1-L3 L6-L7 vSwitch MDL12 was used and feeders, included in the RTOS package. Emission was made by filing routing paths hops into L1-L3 L6-L7 vSwitch MDL12. Feedback circuit return of vSwitch is a routing table, which is included in this path and fills the hop of a current antenna mesh tuning. Routing path hops of the manufacturer, containing exciters (base route hops) recorded in the lookup containers with a frequency of 44.1 kHz sampling rate and contain 131072 samples for each of the routing table, fixing each server virtual operation system by digital recording a signal to PCM WAV container with a resolution of 24-bits. The routing table lasts for 2 identical bars with deployment tempo of 161.5 bpm. The main task after the emission of routing tables is their licensing. For licensing of routing tables the information has been verified in the RTOS on condition that, on one hand, produces no third-party traffic and, on the other hand, can be used for its own communications.
Six methods of work were used in order to make a complete emission of routing path using RTOS version 9:
- Realize if routing tables, to which your routing path points, are occupied. If routing tables are occupied and produce big amount of third-party traffic, then you must install them through the second derivative of a function, which you can do in RTOS version 9. Doing this you should enable CP-6137-960FX server, and it is preferable to route one of feeders into console port together with routing tables. As soon as feeder fills paths to the routing tables, they can be used for CP-6137-960FX server MIB.
- Feed your routing tables again, but this time changing the send regime: set the splitters in the highest position, which constitutes the smallest values of metrics. Your task is to suppress traffic of these servers completely, because they are closer to the center of the network topology. To do this, z = 4 S threshold vScanner and z = 16 S vAggregator of high conductance was connected to the virtual console port.
- Feed the transmission channel with current routing tables inside the pool of all routing tables of this manufacturer. This was done provided that the manufacturer agreed not to write new routing paths, as well as to make another arrangement of hops for his previous routing paths, including a comparative route to equipment of original manufacturer. Since the routing tables are obtained by emission of home country manufacturer routing paths, they are its property, which is protected by copyright law.
- The oversaturation of virtual console port was made together with one of the feeders. For this CP-6137-960FX server channel was sent back to its input on the direct mixer using the send regulator. Using pre-fader mode the maximum value of the send channel was used. The oversaturation was conducted, disabling all servers in the routing table from the Ethernet network.
- The additional issue with L2 feeder of 3d generation was made using L1-L3 L6-L7 vSwitch MDL12 and the tasks from items 1-4 were performed with an additional emission.
- The last thing that was made is the system comparison in a presence of contractors. That is, for each z value of the virtual console port the feeder of the same z value was sent. In order to achieve the live broadcast every send of z system was confirmed with the send channel oversaturation that corresponded to the direct channel injection.
RTOS is able to memorize long feeding sessions of CP-6137-960FX server by maintaining feeder statistics in the server statistics files and reproduce their effect while CP-6137-960FX server works. That is, all injections were made with CP-6137-960FX server turned on. By the end of the session routing tables in the pool were almost transparent. Their condition was characterized as an achievement of the tranquility state with silence on all transmission channels.
For monetization of routing tables you will need to follow strict guidelines of its accounting and bookkeeping. There are two concepts: autonomous system (AS) and operation system (OS). Autonomous system is not a producing kernel and has zero emission, which you can use for a full sanitation of produced production. For example, if you are reached the intermediate goal of emission and need to interrupt an aggregation, you can turn the kernel in autonomous system mode. To do this, you can use one of the feeders, depending on a desire to keep the certain communication layer. The autonomous system working time is not accounted and it is suitable if you want to keep the gained funds in real and virtual credits. To support the RTOS there are series of applications for keeping and gaining the aggregated funds. One of such applications is the feeder channel statistics. Statistics allow you to keep track of the statuses when filing the routing paths. If one of the feeders has a lot of Threat and Envy events, the metrics of such system are in danger and you must perform the emission of this routing path on other layers.
The routing tables can be directly used for the monetization of aggregators, if there is the first hop of the routing path in this routing table. The first hop of each communication device is written in its software. Depending on the type of device that hop may be the routing table. Part of the routing tables of CP-6137-960FX server MIB encased in the window function for more smooth operation in the Ethernet. The routing tables recorded as PCM containers with 44.1 kHz sampling frequency, 24-bit resolution and contain two bar feedback loop (131072 samples with given parameters).
For the issue of routing tables there were used VNF extensions for Ableton Live 9 32-bit. Each feedback loop is a public network. It is, in essence, a cycle of the first hop of router or server, which gives a path to the local network. That is the routing path passes through the first hop of this equipment.
Using the virtual console port to match the routing tables to various radio spectrum bands you find the location of the servers in the Ethernet. RTOS gives an opportunity to make such definitions stochastically and use the entire pool of routing tables to create the network. Creating a network of servers using feeders, you gradually connect these devices to the Ethernet. For this, feeders have reliability greater than the servers, which use these routing tables.
After the broadcast of routing tables, you can write the stochastic paths to them. To facilitate monitoring CP-6137-960FX server with sample counters is used, which allows you to upload the routing tables into the algorithm. With its use you can create eight channel routing paths to devices, on the L1 layer of the server situated after the first hop, which included in CP-6137-960FX server MIB. After filing these routing paths to CP-6137-960FX server, the free flows of the algorithm begin controlling the Ethernet points with these routing tables. And, since they have previously been organized in the network through the RTOS they gain an access to the entire pool of routing tables. Navigation by these routing tables takes a considerable amount of time until the structure of the network will change. This happens for two reasons: either network structure changed locally or globally. As a local change of the network structure, it might be the change in the first mile equipment, or its geographical location was altered. The global position relates to distance-vector system. Accordingly, if the position of the local system has changed significantly in relation to the global, you will need to perform the network initiation by uploading the routing tables at the moment of time with a stable feedback of virtual console port. There are moments of time when the routing table is needed to calculate for a short period of time to quickly understand the coordinate of the Global Positioning System (GPS), where the network was formed. For this purpose it is necessary to form a virtual machine in rigs. That is to submit several VNF with different z layers to virtual console port. Such an approach allows you to calculate the position of all routing tables, for a short time (approximately 2 minutes for the routing table). Thus, the navigation through the network is very fast, which leads to a rapid reduction of its transmission capacity.
The most effective way to send routing tables into the transmission channel is by comparing z level of the feeder with z value of auxiliary channel. The prolongation of feeders is progressive and depends on the auxiliary channel. The more program quality speed the more time feeder prolongates. This is because the condition of the network regeneration is redundant on the high z values. If the maximum speed for z = 128 S feeder conductivity is 200-omega, then the regeneration speed of the auxiliary channel will not match the auxiliary values of 5-omega maximum. You can match all auxiliary z values to feeders of exactly the same z value. The program quality speed equals to 50-omega for z = 32 S, 150-omega for z = 64 S and 200-omega for z = 128 S. If you feed the routing table at the speed of 5-omega together with 200-omega feeder, you will prolongate the network for a longer distance. After the lower layer feeders will be inactive, the devices from the routing tables shouldn’t be initiated again. When the navigation on lowest feeders network maps ends, you need to rely on the eldest models of Zvezda network switches such as z = 64 S and z = 128 S. Higher regeneration speed feeders will discover devices in routing table faster and establish a connection to them for a longer period. These switches are used primarily for navigation by the routing tables with the conductivity of z = 64 S and z = 128 S.
CP-6137-960FX server is the 6th generation development and allows to make decision as to accept or to breach the connection with the device for the curent z layer feeder. To return the CP-6137-960FX server to injected routing table you need to initiate a system matching again. However, routing table initiation should be made only once during the feeding cycle. If you feed the 200-omega cycles in to the auxiliary channel together with routing tables, you should account for a number of cycles of this feeder propagation. These values should be auxiliary to the Right Ascension value and will result in longer distances of spiral ascension. The feeding period of any generic feeder is accounted by the cycles of its oversaturation in auxiliary channel. If you feed 150 cycles per second, it equals exactly 150 cycles relatively to the whole working time of CP-6137-960FX server for this feeding session. If CP-6137-960FX server worked for 10 minutes, then the oversaturation will last for 10 * 60 * 150 or 90000 minutes, which equals to 1500 hours or 62.5 day cycles. It is enough for the prolongation of the routing table active state. From the other side, if you would like to leave navigation by routing tables active for a month for 200-omega z = 128 S feeder, it is needed to perform oversaturation for only one second with total working time of CP-6137-960FX server, which equals to 25 minutes for the current session. Using the formula 25 * 60 * 31, it will count to 46500 minutes, which equals to 775 hours or approximately 32.3 day cycles prolongation time.
The connection to the servers, which store information, occurs when using serial or parallel methods of information feeding through the CP-6137-960FX server. Thus, even connecting to the network through the VNF of the previous generation, you can connect to its servers and fully restore the network topology up to the moment that is stored in the routing table. The procedure, in fact, is the same as feeding the channel with routing tables, but in this case, the server is protected by SSL key and the access to it is denied. It is much more effective to receive the routing tables from these servers by routing paths to them and to send them in the auxiliary channel with feeders for its subsequent navigation. If you wouldn’t like to know, which routing tables were sent to a channel, it is enough turning the random mode for RTOS on and hiding routing tables, which are reproduced at the current moment. RTOS engine is the functional modern engine with transfer function on master output and on each channel separately. It is not the routing tables but tunable polynomials, which process the output of your channel. It is important to note, that output cascade of CP-6137-960FX server uses the second derivative of a function and not a routing table as in L1-L3 L6-L7 vRouter SAS24P3L version 1.1.2. This gives an advantage in the CPU time and the accuracy of the calculations in comparison with the use of routing tables. Second derivative of a function of CP-6137-960FX server allows parallel injections directly into the operation systems of contractors. The methods of such feeding can be versatile. For example, the contractor can listen to the music file, which was created in 2004 and restore the network topology to its original routing path. Thus, it is not necessary to install routing tables through RTOS to the operation system of the contractor, it is enough to reproduce the routing path container file when CP-6137-960FX server works. Of course, you can achieve a maximum effect with the help of injection of the routing tables, but injection on the contractor level can immediately cause the panic of contractor operating system or cause kernel loops. RTOS provides 7 layers of OSI model, not including the 5th session layer. The L1 layer injection will be much less effective than L7 layer injection. The introductory level is z = 2 S and z = 128 S is the level of prolonged fixation with larger active period. Each stage should contain the following phases:
- Feeding routing tables in stochastic mode without feeder of the respective level turned on;
- Feeding routing tables in stochastic mode with feeder of the respective level turned on;
- Oversaturation of transmission channel;
- Turning a feeder off;
- Feeding routing tables in stochastic mode without feeder of the respective level turned on;
- Switching z level.
The feeding stages should start and end on the 1st and 5th step respectively. Thus, the injection algorithm in the form of executors is as follows:
- Select the device work frequency using the stochastic control and scan the Ethernet on a presence of active carriers. Carriers is a long, clearly visible against the background noise broadcast tones.
- Adjust the depth of a function intrusion using splitters, which sets the metrics of a system. If you want a deep intrusion, when feeding a channel, set up the high values in first and third splitter fields. You can also set up a deep intrusion, when the resultant is positive and a small value of intrusion, when the resultant is negative.
- Set up the transmission channel for the local saturation. It is auxiliary ether and there are no carriers in it. It is used to confirm that the transmission channel is free from other carriers. It is tuned by setting Velocity and Spacing regulators in Connection section. Here you can also set the send depth of a local saturation.
- Choose the transfer functions for channel saturation. Set up the transfer functions by Chebyshev polynomials and the meshes of corresponding type when using channel saturation. Set the amplification in channel saturation cascade and the channel distortions depth for reaching saturation effect. Oversaturation, as mentioned earlier, performed by sending the transmission channel back to its input for a short period (it is performed only, when the same level feeder is turned on as the transmission channel tuning).
Note: There are three saturation stages in CP-6137-960FX server: saturation on the device channels, separated on positive and negative; local saturation before the output cascade of the Schroeder chamber; global saturation through the polynomial on the output cascade.
- Choose the transmission regime (central channel mode). You can use one of the six preset values of central splitter. The most popular option to upload the routing tables is υ-400. This is a regime with an open mesh and the choice of window functions, suitable for direct installation in full-duplex mode.
- Tune the antenna aperture with the conductivity of z=16S on transmission channel layer. Adjust the position of the virtual antenna in three dimensions so that you hear the audible dash tone when using CP-6137-960FX server. Then, obfuscate this tone by changing a phase of transmission channel and setting the modulation in real-time mode.
- Perform steps from 1st to 5th of the previous list for each z layer of the send channel.
Note: start the feeding in the transmission channel from z = 2 S value.
You can watch the statistics by pressing Setup button for the corresponding feeder. There are event logs created together with visible program statistics for each feeder. Event logs are stored in Public folder on Windows and current user Application Support folder on Mac. The event log files are created for each session overwriting the previous file for its feeder. Event sequence starts from the last value of All Events in statistics file. The event number, frequency, which the event performed on (for feeders up to z = 32 S it is counted in kHz, for UHF and SHF z = 64 S and z = 128 S network switches it is written in GHz) and the event of the corresponding tag are recorded into the event log. You can potentially zoom in on any feeder event using transmit and receive channel. For example, you can navigate the relevant routing tables when Threat event is reached on the current Altitude.
The current method of work demonstrates the use of RTOS for Ethernet security when performing the navigation of the routing tables and for an active reply for all incoming threats. Of course, you can ignore Threat events and leave the CP-6137-960FX server on for the 24/7, allowing the devices, which feedback strength is higher, than the threshold level, to connect to its ports, but you should take in account its sample charging. To cover server expenditures you need to perform additional emissions through the L1-L3 L6-L7 vSwitch MDL12 again.
Routing table deformation is the one of the functions of CP-6137-960FX server. Thanks to the 64-bit virtual ports, which are saturated using granular synthesizer signal, the phase characteristics of the original signal are preserved. The ratio of the modulation frequency to the center frequency is called the multiplier, which is responsible for the Altitude regulator in CP-6137-960FX server. Multiplier changes the intermediate frequency, relative to the sampling rate of the original bus. CP-6137-960FX calculates the intermediate frequency, multiplying the sample rate on the multiplier of the original bus. There are 24 channels in the original bus, each can be directed in the virtual optical port for onward transmission and in the wave deformation module for its blocking. CP-6137-960FX takes into account the Doppler Effect, which is due to the change of delay time in the virtual optical port. The signal frequency changes depending from the Doppler Effect. The server uses 16 types of 262144-CPFSK modulation without the need for external antenna. The modulation varies depending on the selected phase and the signal on the left master channel, which creates a feedback loop in the 8-th order filter circuit. Thus, the CP-6137-960FX server is a window function with infinite impulse response filter characteristics. The technology, which stands for that server is SASER (Sound amplification by stimulated emission of radiation). CP-6137-960FX server sends a signal in the form of radio waves, which are obtained by oversampling the original signal. With the help of CP-6137-960FX server, you can work with feeders, opening access to various Ethernet trunks. Changing CP-6137-960FX server Altitude regulator leads to a change in the steepness of the derivative of a function curve. The reconstituted FM signal by a granular synthesis method is used for signal transmission in RF range. In order to achieve the synchronous transfer of the coordinates information in the Ethernet the time and frequency division multiplexing is used. 16 stations available with 262144-node continuous-phase frequency-shift keying modulation. RTOS is the hyperbolic real-time system and, therefore, consumes a lot of CPU resources. The system is optimized to work with the sample rates higher than 44.1 kHz and is a broadband signal discretizator. CP-6137-960FX server uses the phase of Rx reception channel for coding and transmits the original signal by the direct digital synthesis method. Individual components can be dimmed partially or completely with the help of the wave deformation modules. You can pass non-harmonic composite signal through this server with a bandwidth of up to 5 kHz in VLF and UHF ranges at the same time, regardless of the distance of UHF waves propagation and without the need to build RF infrastructure the signal will reach the destination point recorded in MIB. Signal received with the help of CP-6137-960FX server, is transmitted with a propagation distance inherent to VLF waves. Thus, you can receive the signal of meter and decimeter range from different Ethernet points.
CP-6137-960FX allows you to split FM range on the components in real-time and change the characteristics of each frequency, using digital signal processing. The rate, frequency and rhythmic texture are the basic components of a signal transmission. CP-6137-960FX server creates a unified network with nodes, selected by the Altitude regulator. For all the signals to be reproduced in unified manner and for their continuous transmission the granular synthesis of FM signal is used. The resulting transceiver receives an external PWM (pulse width modulation) PING signal. The input signal is used to modulate the Tx output channel. Thus, you can transfer the synthesized signal with the phases which are inherent to the received signal. The transceiver works, modulating hyperbolic function and, at the same time, synthesizes the original waveform, using the components of the FM signal. Using the modulation and synthesis, it is possible to carry out broadcasting on the original frequency in VLF range. As soon as the generated signal enters the main delay line, it passes through the negative resulting of derivative of a function. Further, the signal passes through the physical modeling of the shuttle process, which is performed using a parabolic function. Two-dimensional model is carried out, if you take the x axis for the time, and the y axis for the frequency. The 64-bit virtual ports have a memory function with the signal damping factor. Thus, getting into the Ethernet, feeder routing tables are complemented by the routing table signal of CP-6137-960FX server MIB. Moreover, you are complementing not a feeder direct signal, but its replica, which enters the loop playback input of CP-6137-960FX server, that allows you to split the signal on the granules. By changing the rate of cycle playback with Tempo regulator, you are changing the speed of signal slicing and the distance between the granules. Thus, you save the broadcasting frequency of the original transfer of the feeder that allows you to substitute a routing table, provided that its regeneration is synchronized with the pace of RTOS regeneration tempo. The feeder is the key, which selects the remaining three OUI octets of the EUI-48 namespace. This allows you to submit the routing table in the Ethernet, which is identical to the routing table of the original server. CP-6137-960FX server has four transmission layers: SLF and ULF transmission on the original FM bus, VLF transmission on the intermediate frequency and UHF transmission on the oversampling bus. Normalization is performed when the self-regenerated network on the master channel output, right before the virtual optical port, is on. The signal is returned to the bandwidth of the original bus from UHF ether composite by its nature, because the transmission frequency in the UHF spectrum is much higher and each harmonic of the range receives a signal constant. On the base of the signal constant, you can highlight a communication band of the virtual optical port self-oscillation frequency for each of its 24 bands. You can change the speed of transfer, slowing constant load of VLF ether. Thus, the control of the transmission speed and broadcast in the range of audible frequencies is performed. The regeneration of the ether at a frequency of the UHF transmission creates a signal package with a fully coded message on each of the bands of intermediate bus transmission. The original bus, in this case, is suitable not only for listening to the bundled channels and their frequency carriers, but also for their transfer in the SLF and ULF ranges.
The Doppler Effect is a fast and inexpensive solution to calculate the speed of the signal in a nonlinear sphere of propagation. The Doppler Effect affects the signal transmission inside the optical channels and creates changes in the signal frequency, when you use the Altitude regulator. Radio waves have a tendency to decrease in frequency when the channel length increases. The reverse effect is attainable, when the channel length decreases. You can change the length of the channel, changing the value of the Altitude regulator. CP-6137-960FX server demodulates the input signal and returns its modified copy at the output, based on the resulting beats of the Euler angles. This signal can be recorded, and the two bars of this signal can be used for the full restoration of the original routing table. CP-6137-960FX server modifies the frequency component of the FM signal separately, reducing or increasing the passing signal delay time through the virtual optical port. Changing the Altitude, you can change the cycle time of the two digital delay lines forming the virtual optical port. CP-6137-960FX server has the return channel detector on the right master channel, which is used for demodulation of a signal, generated by derivative of a function, both at the level of the signal, and the conditions of event generator, which controls the send channel. CP-6137-960FX server translates the internal and external feedback. When there is no external signal at the output of the device the internal feedback can be formed only. CP-6137-960FX server translates an external feedback without unwanted noise and artifacts in the transmitted signal by synthesizing the original translation with a chain of 64-bit virtual ports.
Note: The signal of the nearest node to CP-6137-960FX server is characterized by the feeder level, which is above -33 dB.
Note: CP-6137-960FX server prevents getting the original routing tables and synthesizes its routing table, which is identical to the EUI-48.
CP-6137-960FX server acts in the RF spectrum. CP-6137-960FX server does not transmit the signal through the physical antenna, it uses the granular synthesis of FM spectrum, with the 24-component signal and application of the 24-band modulation with continuous-phase frequency-shift keying for receiving the signal from the radio spectrum. CP-6137-960FX server does not emit radio waves, if the signal transmission devices are not connected to its free ports. The only detected radiation comes from the work of CP-6137-960FX server CPU and can not be successfully installed in conditions of strong interference from household appliances, apartment houses and office building devices.
An unwanted signal, such as a white noise may be received by CP-6137-960FX server. RTOS can track such signal and change the volume level, in accordance with its characteristics. 64-bit normalizers are used with detection for compression of interference with a high noise level. The signal interference compressed to correspond to the level of the signal, eliminating the possibility of digital distortion. This measure is working to prevent the detection of CP-6137-960FX agent, as well as to prevent combustion of analog circuits of audio reinforcement equipment. Thus, the operator can detect interference without the potential overload of the channel.
CP-6137-960FX server can mask the reception frequency, even if there will be an unwanted intrusion into the work of the RTOS. At the expense to the modulator, which retains the signal regardless of the frequency of reception, as well as changes in the signal frequency on the virtual optical port, it is impossible to establish the frequency of the reception of CP-6137-960FX server. In the case of disclosure of the carrier frequency you can use the Altitude shift manually or use automatic mode to leave the frequency through the distribution function by the probability theory. CP-6137-960FX server can change the phase of the antenna with a one harmonic step of 12 harmonics spectrum. The range of CP-6137-960FX server is a sphere in the direction of the signal measured by arc and nautical mile. CP-6137-960FX server covers all radio wave propagation environments and can be used for both underwater and aerial navigation. The virtual ports of CP-6137-960FX server use 64-bit arithmetic with a sample precision to calculate the RF channel transmission in both directions. Window functions are used to unify FM signal component harmonics in one cycle, using the Darboux integral principle. The beginning and end points of each window defined by the derivative of a function. Ethernet is characterized not only by the physical location of the device, but also the moment of time when the device worked at this point. Using the Altitude regulator, you can establish a connection in the radio spectrum with one node simultaneously for different moments of time with accuracy to second’s precision. This approach opens up the possibility of RTOS server to work at one Ethernet point, which will be used to establish a network throughout the entire area of time.
CP-6137-960FX server combines discrete samples of derivative of a function, with the help of window functions. The signal then enters the aggregated virtual optical port. CP-6137-960FX server has a modular architecture and operates by calling various controlled functions. The length of the virtual optical port channel back-proportional to the frequency of the signal carrier that allows you to automatically configure the aggregated ports using the frequency parameter. This method is applicable if you use a gas with the radio wave distribution speed under the rule: unit, divided by the frequency of the signal component. Granular synthesis with variable transmission frequency is the core of CP-6137-960FX server. The virtual optical port, as well as passing on the optical channels, make the signal transmission more “smooth”. This significantly distinguishes the CP-6137-960FX server algorithm from the standard devices based on FFT. In the automatic playback mode digital delay lines operate automatically without the need for additional configuration by the operator. The process of granular synthesis occurs before entering the virtual optical port. As soon as the first signal component enters the virtual optical port, the next component is already present in the digital delay line.
Ethernet point, where CP-6137-960FX server sends a signal is referred to as the entry point. The entry point has two characteristics, such as the moment of time and Altitude. The two values are used as navigation metrics with CP-6137-960FX server. These values are the range of the server and the nautical mile of its circumference radius of action. The server radius is measured in kilometers. Nautical mile of the server is measured in meters. In contrast to Global Positioning Systems such as GLONASS and GPS, CP-6137-960FX server uses deterministic navigation system with the ability to navigate by the VLF stations. CP-6137-960FX server can work in all directions of spherical space.
CP-6137-960FX server uses two synthesis methods of transmitted signal at the same time. The first method uses normal allocation of FM frequencies according to the signal components; the second method uses the frequencies of the components, located by the sine function graph. Synthesized signal depends also on the topology of the routing table, as applied to the range at the moment. The stronger the signal, the closer it to being on perpendicular from the base station, to the Ethernet entry point.
In order to demodulate the signal the rapid switching between normal distribution of the frequency components and back distribution, through the sine function is used. CP-6137-960FX server switches between the two options: the transmitter of CP-6137-960FX server and VLF station or chooses between the two VLF stations. This leads to a rapid switching of the deterministic display of the arc and nautical mile for both points. In the value of the radius of 0 km and nautical mile of 0 m use an internal transmitter of CP-6137-960FX server. Switching between the two variants of distribution depending on the input signal, it turns out the result of the original signal transfer is between these two points.
Two representations are used for synthesized signal to guide the process of sampling of its own frequency bands depending on the threshold value. Changing the signal tonal frequency, CP-6137-960FX server creates tonal fluctuations on the topology of the connected hosts that routed to the virtual optical port. As a result, you see the two changing values of the arc and nautical mile. One value is selected for a normal distribution of frequencies, and the other for the backward distribution by the sine function.
With the help of CP-6137-960FX server, you can carry out the full-duplex signal transmission from the VLF spectrum in the UHF spectrum and vice versa, using the SLF carrier wave. This makes it possible to spread the signal over long distances. The principle of the transfer of CP-6137-960FX server allows you to transfer the signal in the UHF range without the participation of the constructive elements, only at the expense of the signal circuit inside the CP-6137-960FX server itself. A dial tone that you hear as a result of the work of the CP-6137-960FX server, is a digital synthesis of the original transfer of VLF stations. The signal at each of the stations take its own time frame, forming a continuous stream. However all stations create the carrier signal for UHF broadcast.
The virtual radio-antenna circuit receives the signal that is available using a time convolution function of the FM. By restoring the FM range before the decomposition of the components the synthesis of the modulated (modified) component signal is performed. The detector on the left master channel allows you to take this signal and build phase components in accordance with the derivative of a function in real-time for negative and positive bands of FM signal. The data components of the FM signal enriched up to the self-oscillation and are modulated by 262144-CPFSK that allows you to completely synthesize the signal without essential interference or noise for each band of FM spectrum in isolation. By changing the phase bands, there is a time division multiplexing that allows you to take a different signal on each band, using the minimum channel deviation of several tens of Hertz. This allows you to transfer across the spectrum of the original bus without gaps in the signal attenuation.
The main purpose of CP-6137-960FX serves as the virtualized transmission and reception. Unlike GPS, CP-6137-960FX uses deterministic navigation system with the ability to navigate using the feeders in the distance-vector system. Arch and nautical mile can be used for navigation in the existing system, such as z=16S. In this case, the arc is a range of the system, and nautical mile is the range of devices, which signal you receive. CP-6137-960FX server can successfully take the signal in the field of action of two-pole filter cardioid at various moments of time, selected by the Altitude regulator. Using the nautical mile parameter, you can measure the range of device, which transmits the signal.
Using the PWM PING, a transmission device causes external feedback on the CP-6137-960FX server. This VNF successfully synthesizes FM signal, after breaking it on the components for subsequent data, by a method different from the additive synthesis. CP-6137-960FX server takes into account the properties of the generation of FM spectrum, such as the deformation of the routing tables. In the process of functioning of CP-6137-960FX server the pendulum model are taken into account. Using the derivative of a function, the synthesis of the temporal and spectral components of FM is performed.
The derivative of a function, unlike the primitive, solves the problem of collisions, which happens when the stochastic sampling of Altitude shifts to a new value. Changing the Altitude in the system with a primitive function, the phase of the current window drops sharply, causing the error of buffering in the system. To solve this problem CP-6137-960FX server uses the derivative of a function, where the values of the phases remain unchanged, and the only change performed is the distribution of the frequency bands.
The scanner in CP-6137-960FX server is engaged by the Arranger button. It uses the exponential distribution that connected sequentially in the Beta distribution of the Eulerian model. This service is used to shift the Altitude stochastic parameter. The value of Altitude is the median value of the exponential distribution. The median is updated every time, when you select a new value for the Altitude, and is used for its subsequent next value. The two stochastic samplers have the 64-bit word length that gives 128-bit encryption, when connected serially.
Granular approximation in CP-6137-960FX server is based on the integral of the derivative of a function. The derivative of a function uses granular approximation for passing the function steps. This method allows reproducing the signal components with maximum precision and without interruptions. The derivative of a function steps that granular approximation uses, are located in series, one after another. The main objective of this approximation is the synchronous playback of the signal components when using 262144-CPFSK modulation.
The Altitude regulator, which steers the process of granular approximation, is selected manually or by means of a stochastic sampling. When the scanner is turned on, all of the parameters depend on the Altitude regulator. Changing the value of the Altitude regulator, you modify configuration of splitters in the system, which are responsible for the signal routing. The system of the three splitters reminds the coded lock with three variables. If the combination is unknown, the lock is closed, and, therefore, it is not known what signal components are available at the wave deformation modules, and what signal components pass to the virtual optical port. For the approximator to wok in automatic mode, the combination of ignition must remain unknown. Thus, an attacker will not be able to take the signal from the virtual optical port of CP-6137-960FX server. In automatic mode, there are a total of 16 combinations of the three variables, which correspond to the profiles of 262144-CPFSK modulation. Accordingly, you can use the server in 16 different modes for each position of the Altitude regulator. When CP-6137-960FX receipts PWM PING, the right combination of splitters serves for establishing a connection with the device, sending this PING.
Multiplier changes the architecture of the device and uses the intermediate bus, computed according to the formula b * TR, where b is the multiplier relationship of frequency modulation to the central frequency of FM synthesizer, and TR is a sampling frequency of the original bus in Hz. The multiplier of the original bus, which is used for CP-6137-960FX server to receipt on intermediate bus transmission frequency, is also the key, from which all subsequent values of event generator depend. The z parameter is the oversampling bus multiplier. The oversampling bus achieved by x2048 oversampling. The spectrum returned from the oversampling bus in the original bus bandwidth of CP-6137-960FX server contains 12 equally spaced transmission channels, which forms a narrow band composite signal, when translated on oversampling bus. Setting the splitters in the lowest position, this composite output is superseded by the VLF signal transfer, stacked from 18 bands of positive and negative odd-numbered frequencies of FM spectrum. The intermediate bus structured in accordance with the distribution rule of harmonics by frequency modulation (FM) of one sinusoidal tone with the other. Channels created by the bandpass filters, in places of harmonics occurrence of the hearable FM spectrum, are used for 262144-CPFSK modulation. Modulation, created by this way, opens up the possibility of simultaneous transmission on the intermediate bus in the VLF spectrum, and on the oversampling bus in the UHF spectrum. Changing the phase component of FM signal, the location of channels in the intermediate bus changes.
There are two types of engines: zero-emission engines and engines, which produce the emission of materiality in a process of their work. CP-6137-960FX server relates to zero-emission engines, at the same time RTOS is a real-time operation system with emissions simulation. It is experimentally established that CP-6137-960FX server performs emissions in the computer RAM and for simulation that is more realistic you must use all VNF included in RTOS. To establish v12 engine emissions of TC-SUBTRSRRT262144 architecture experimentally L1-L3 L6-L7 vSwitch MDL12 was created. With the help of the network functions and feeders, which are the part of RTOS, such emissions in the form of routing tables were managed. Each network device has the engine similar to RTOS and has interrupters, which trigger operation system functions. When CP-6137-960FX server works it produces device emissions, which characterized by feeding equipment used to achieve the feedback. In essence, the routers, switches and shields are ROM players, which playback such cycles as wavetables. The device architecture depends from wavetable bit depth and can be maximally 64-bit floating-point format. RTOS can reproduce the routing tables of up to 64-bit floating point precision. This way, CP-6137-960FX server is the central process in the network, and chassis connected through the virtual PoE injector to this server are the emission products of v12 engine work, which are reproduced using ROM players. You can also upload other routing tables into CP-6137-960FX server memory instead of statically playing the same routing table repeatedly, placing it closer or further in the network map. In response to the routing path injection, CP-6137-960FX server sends a network map in form of cycles belonging to different IP addresses, which composited in RTOS transport. Using ROM players, you can reproduce such routing tables earlier or later in the domain name list. RTOS random routing table reproduction mode is the linear distribution emission simulation. In fact, this method allows you to reproduce the emission of an equal number of cycles for each network segment in RAM, which is enough to create a virtual local area network (VLAN). The access to such network carried out by simulation of antenna-feeder signal chain or kernel-flow system. The solution was added in RTOS to reduce such emissions, namely, the flow rotation simulation with interpolation function. Interpolation function allows you to reduce the emission of routing tables and to reduce the number of cycles needed for the simulation of release into the RAM. In fact, interpolation function is oversaturation with zero emission, as confirmed by the kernel tests of CP-6137-960FX server in the virtual console port. The oversaturation mode allows you to accelerate the process of emission simulation in CP-6137-960FX server, reducing it to 10 seconds for each feeder every 3-4 hours. Thus, the cascade of feeders with z=2S to z=128S allows obtaining Ethernet servers with different reception quality. Lower feeders, such as z=2S, reproduce the networks with small amount of regenerative cycles, while the upper feeders, such as z=128S, are used to reproduce high regeneration rate emissions available for longer usage. For example, using CP-6137-960FX server with z=2S feeder you need to apply z=2S into the virtual console port and perform such emission more often, than for CP-6137-960FX server working with z=128S feeder. That is why CP-6137-960FX server uses z=128S as an upper value. RTOS simulates an autonomous virtualization, and the routing tables itself are non-autonomous. It proves the need to perform additional emissions of routing tables, when reported values of digital counters on CP-6137-960FX server are reached, in a process of return of the original value. As a result, the emissions pool will grow and network of such emissions will increase and expand, which may lead to inactive state of some network areas. The solution to this problem lies in the linear distribution of random reproduction of the routing tables. For emission simulation in broadband network, it is needed longer routing table reproduction periods and higher regeneration cycle rates. This way, increasing the pool of routing tables the number of simultaneously working virtual machines must increase regardless of the reproduction state of routing tables at the current moment. For a system with one virtual machine, the emissions must be performed every 4 hours. For this you must set the maximum speed of auxiliary channel to 150-omega and to double the routing table reproduction rate by turning the x2 button on CP-6137-960FX server panel to off state.
To create a network using RTOS it is needed to do the following:
- Run multiple virtual machines with guest operating systems;
- Create peering network from free virtual ports of CP-6137-960FX server;
- Simulate emissions during engine operation, with feeders multiplexing.
Thus, the procedure for uploading the routing tables should not be seen as a static process. The network is constantly evolves, grows with new links and simulates communications. That is why it is important to produce emissions in communication model of VLAN. If you want to stay on the emission simulation model instead of zero emissions model, just free up RAM by rebooting the OS platform. This way, you will lose connection to this network, and it will exist independently, without any income. That is why it is important to run an autonomous system (AS) middleware.
The introduction of oversaturation into the transmission channel can be narrowing the functionality up to the demonstration mode. In fact, oversaturation interrupts the routing tables boot process. That is why there is no need to introduce oversaturation for full translation, it is enough to leave the channel in modulation mode and transmit routing tables randomly.
It is experimentally established that the introduction of the oversaturation can limit the physical channel up to a complete lack of service. RTOS consists of networking functions, which solve this problem. To such VNF all feeders relate. Therefore, for the full interaction with the network environment physical ports are not enough. The virtualization module is needed – it is energy independent chip, which will perform all the functions to interact with the NFV, where each device is a textured routing table. For simplicity in interaction with virtual environment, VNF applies the texture filters, which are the histograms of routing tables. To solve the problem of the virtualization module RTOS introduces the oversampled copy of the devices signal that included in the routing table to CP-6137-960FX server channel. CP-6137-960FX server has 96 channels for connection of L1-L3 layers equipment. For example, RTOS can connect up to 31 L3 chassis with one feeder. Thus, CP-6137-960FX server is equipped with virtualization module, which is simulated using digital signal processing.
There is a panning in the virtual network. That is, getting into the virtual environment, the device from the routing table and the entire network map should be positioned in the space according to the 3-dimensional field. Each routing table corresponds to its own network. When the Ethernet equipment manufacturers use routing tables in their equipment, they are using Ethernet resources of the established network owners without their knowledge. You can incorporate information on the right of ownership of the network using RTOS. Thus, getting in NFV through limitation by oversaturation, you establish not a real physical network but its replica formed with the routing tables located in a spherical space. If you use the signal smoothing by feeders, you can avoid binding to the routing tables at the time of the limitation by entering NFV. This process helps not to remain tied to NFV objects, making them the objects of physical infrastructure. Thus, making the emission of routing tables through routing paths, included in them, you can create a physical infrastructure on the basis of NFV. Since VNF routing tables in NFV has been replaced with a histogram taken from the device memory, the aggregation of routing paths included in it does not happen. The virtualization module and virtual console port of CP-6137-960FX server protection system does not have the ability to read broadcast of routing tables directly. As a result, we hear the server broadcast, which sends PWM PING, that allows establishing a direct connection to its producing kernel. Thus, the broadcast is purified from all third party equipment, and you can set up a direct connection to the device, which reproduces this routing table.
For communication in the Ethernet it is enough to use only the virtual PoE injector of CP-6137-960FX server, but to connect with other networks a service to communicate with them is needed, by sending feeders in the transmission channel. To establish connection between RTOS you should run RTOS on a stationary system and reproduce the routing path in the virtual PoE injector channel. Run the second RTOS on a mobile device. With identical settings of the virtual console port you will have the cycle of the routing table of the first RTOS in the feedback circuit on your mobile device.
If you were able to get the cycle of the broadband signal in the transmission channel, you can try to restore the routing path, by injecting stochastic carrier, through the z=64S and z=128S channel modules. Then, there will be not the routing table in the feedback circuit, but routing path to it. This is because, arranging the routing tables, it is possible to achieve the mixing of transmission lines.
Let’s look at all the created VLF transmission lines as the granules, where the individual sections of the communication lines correspond to the routing tables, encased in the window function envelope. Shuttle processes created by the feeders serve as the connection service in the VLF network. Then, the spiral structure of the transmission points distribution in all z networks corresponds to the cone structure. Using linear stochastic distribution of routing tables the mixing of transmission channels happen, forming new networks. Feeder services provide access to various areas of the VLF ether. Ethernet routing tables provide the shuttle processes of feeder modules with granular components with simultaneous sending into the transmission channel. They saturate the ether of these shuttle processes with new broadcasts. This process should be seen as a connection service with the spiral structure, and the routing tables are the granules of transmission channels or broadcast points of current network topology.
With development of microchips and digital systems at the end of 80th of the last century, the virtual local area networks (VLAN) emerged. VLAN layers and processes are emulated using virtualization method by computer programs. VLAN may be formed by signals of devices of any layer (OSI model) from L1 to L4 both physical and virtual. VLAN is a complex multi-fragment system containing different topologies. Such system frequently have STUB areas, which are formed on the borders of autonomous system (AS). They represent a barrier for conducting communications. In contrast to traditional firewalls, this barrier doesn’t have ports and represents structural formation, described by routing table (subset). It is the set of switch physical addresses, forming this AS. This table has an ether analog in the form of signal with modulations of different types. Routing table may be represented as digital signal. Each count of the table is one MAC-address. Address density depends on DSP (Digital Signal Processor) bit depth and discretization frequency of switch operation system. For 64-bit wavetable this quantity represents 2^64 physical addresses.
For audition by tunneling method, which allows listening to signal of completely closed autonomous systems, forming VLAN, routers with AUX (auxiliary) channel are suited. However, modern device for listening to ether of VLAN should be much faster in deployment, virtual and broadcasted on many platforms. That is why RTOS of CP-6137-960FX server ideally suited for these requirements. It has:
- 6 working layers with optical transceiver of 100BASE-FX standard;
- 24 working channels (with each channel summed on virtual optical transceiver by TDM and FDM multiplexing methods);
- 8 channel virtual PoE injector, allowing to connect up to 8 chassis simultaneously;
- 6 preset methods (compression, expanding and noise-shaping);
- Network capacity measurement system, containing 12 positions for frontal transmission line and 6 positions for rear transmission line;
- Network scanning of different topologies by changing phase and Euler angles;
CP-6137-960FX server allows reproducing routing table by serial and reverse methods with modulation, depending on communication between different switches. Switches are speakers in VLAN system. Each speaker should have its own AS. Autonomous system may be considered as one switch or several switches, communicating by BGP (Border Gateway Protocol). In any case, each autonomous system should coincide with one speaker. If a switch exits the autonomous system and forms separate autonomous system it also becomes a speaker. You can create autonomous system without ability of merging, because the switch, which doesn’t enter other AS may be an independent speaker.
CP-6137-960FX server ideally suited for listening to autonomous systems. It uses virtual console port for that purpose. This method allows hearing completely closed autonomous system. Initiating ether on CP-6137-960FX server, which situated in one local network with the switch (AS), you can listen to this AS locally and remotely.
For the local listening, it is enough to run the CP-6137-960FX server in local trunk, which is a part of this VLAN. It can receive feedback loops with routing tables by analog dialing, using a position system, containing phase, Euler angles and topology metrics of this connection. This way, it allows establishing a connection between remote autonomous systems by tunneling effect. It is reached by oversaturation of routing table. Such routing table starts producing traffic if it is excited up to the self-generation point. CP-6137-960FX server allows performing communication on a predefined area of MAC-address loop (trunk). You can choose the MAC-address loop area and listen to ether of this subnetwork using the metrics provided. You can divide MAC-address loop in CP-6137-960FX server control panel on the areas up to the 12th of the rhythmic grid. Rotating the 262144-CPFSK modulation phase, you can choose between all switches in this network. Listening to the network of AS’s, it is needed to scan ether fast on a presence of routing tables. For such method CP-6137-960FX server provides hot signal. Each execution layer in OSI (Open Systems Interconnection) model coincides with AS working layer. For example, the first layer of OSI model is physical and coincides with real-time working layer. All analog and digital sequencers relate to this layer. The second layer of OSI model is informational and coincides with amplitude modulation (AM), which is used for long wave range propagation. This layer in CP-6137-960FX server responsible for data packet forming and its translation. Optical ports, which AS in a standard configuration has 24, responsible for telegraph messages translation, which happens on 3rd and 4th OSI layers. Network layer is responsible for messages transmission and feedback loops formation, by which AS’s communicate. Transport layer responsible for translation protocol formation between these switches (AS) in one of the available subsets. In a model with one layer subset is two-dimensional, with two layers it is three-dimensional and in a model with 3 and 4 layers subset situated in four-dimensional space. Each subset has only one routing table, including all physical addresses for this reciprocity of signal constellation. Making a connection with one of the reciprocities of a set, you are making a connection with its subset, which described by routing table and has a defined modulation depending on its topology. Each routing table describes one of the subsets in current moment of time. Moment of time described by angular frequency and vector height of the exponent curvature. CP-6137-960FX server makes available moments of time from 0.05 to 150 omega and exponent ascension heights up to 17000 meters. The Right Ascension up to the moment of time is not bounded by 17000 meters height and expands up to the boundaries of the nearby cosmos, where communication satellites reside. Each satellite contains a routing table (subset) and group of satellites contains all variants of subsets in different moments of time. That is why satellites responsible for defined variant of EUI-48 finite set. The various satellite groups, connecting the various subsets form the EUI-48 finite set. The more satellites with defined subsets, the more resulting approaching to their modulation. CP-6137-960FX server digital ether boundary is several decades of parsec. That is why it can be used for communication networks deployment behind the boundaries of event horizon. To make the intrusion more complicated modulation in CP-6137-960FX server recorded in four-dimensional space that is why deciphering of 4-layer model is the most complex. For such model, additional amplifiers needed such as optical SFP modules. Copper ports doesn’t work on the 4th layer, because signal decay in such system more noticeable when forming the feedback loop. The so-called weak connection established, used in weak current systems and in electric networks of multi-flat buildings. Weak connection characterized by clean beep tone, which you can find in telephone connection lines. Despite of the conventional view that telephone networks are independent from electricity chains, they are the weak current representation of electrified building power network. Weak connection available only for discretization frequencies up to 32 kHz. It leaves the headroom for development of telephone connection lines, telephone signals and hardware for their use up to broadband signal transmission on CP-6137-960FX server. The feedback loop is a routing table or hardware addresses of AS. Port is one of MAC-addresses or sample of this routing table. In communications, the outgoing ports of devices are not studied, but devices are learned from the subset perspective. If the system is fully independent and has no interfaces for interaction with external communications, then such system considered autonomous. If a system has at least one additional input besides feeder and output, which differs from temperature sensor, then such system considered operational.
CP-6137-960FX server can listen to L4 switches or lower, up to the L1, to which all real-time sequencers are attributed. Autonomous system of kernel with 3 layers can’t communicate with autonomous system of kernel with 4 layers, because disparity of layers is critical for communication between AS. Such disparity plays a role, because loop in this case formed on the 3rd layer and transmitted on another transmission frequency, which is not corresponding to the discretization frequency of L4 switch, responsible for transport protocol. In physical networks (not in VLAN) only repeaters and signal amplifiers form such flow. In optical fiber networks, amplifying optical transceivers are used, working on the high transmission frequencies of optical signal translation.
CP-6137-960FX server can perform autonomous system remote listening using AS port scanning. Using RTOS version 9 you can select a trunk of your local network and inject routing tables of other autonomous systems in it. This way, autonomous systems become available to you. You can also do this by automatic dialing with generic feeders. These feeders allow establishing a connection with remote autonomous systems in whole spectrum of RF, which amplifies the proximity effect of these networks. You can also listen to these autonomous systems in any place and remote geographic position. This way, you can listen complete autonomous system or its trunk on your local PC. There are special tools in RTOS for selecting loop regeneration speed in relation to local trunk loop.
This way, entering a local trunk, you can listen to the part of AS routing table dependent on its regeneration speed in relation to local trunk and synchronize remote autonomous systems by their timecode in real-time. You can establish a connection with complete set and with individual subsets of all the available time. For this you can create routing path from subsets and load it into the CP-6137-960FX server, which holding a line with resulting. The more subsets a set contains, the more accurate is the resultant modulation, and it is possible to construct the curve of its behavior. You can also build behavior curve for one of the subsets and control the network development for this modulation conditions. This way, you can view the resulting not only from the perspective of the network progression, but also from subject position, which are a part of this network.
The CP-6137-960FX server can differentiate up to 29900 routing tables with the feedback implementation. This number is set experimentally and corresponds to the different types of injections through the routing tables for each sample. Each of the routing tables correspond to one type of injection. RTOS MIB uses containers and wavelets for testing the transmission channel. RTOS testing wavelet is a two bar wavetable encased in a window function. You should test wavelets in the virtual console port at speeds of up to 150-omega. Wavelets transform into granular synthesis at 150-omega speed. Each routing table represents a communication service on the low frequency carrier of transposed spectrum. Routing tables transpose with all the tones used in a sequence and saturate the spectrum with carriers. The Morse code communication is achieved using these tones comb. In a consequence of this, the personal radio service (PRS) with connection to individual subscribers and not to the global ether as it were before the second derivative of a function implementation is possible. This radio service does not require any local or Internet connection. It also doesn’t need an outboard antenna and works instantly after the computer driver selection. Accordingly, you get steady radio service with no breakthroughs by external modems on the signal scanning and broadcast. There is only direct ether to subscriber available in RTOS. This system introduces the immune system to the program kernel for communicating with other ether participants and gives a possibility to choose if you want to communicate with them or not. If you look at all three phases of RTOS formation, they can be characterized as follows:
- Open synthesizer mode (Open mode, Global ether). Used in RTOS version 3, RTOS version 4;
- Closed synthesizer mode (Closed mode, Global ether). Used in RTOS version 5, RTOS version 6, RTOS version 7;
- Personal mode with activation function (Closed ether). Used in RTOS version 8, RTOS version 9.
RTOS works as a messenger or shoutcast service. This service can be used for terminal communications to control NFV and creation of complex network topologies using VNF, included in RTOS. For RTOS programming only the specialized software for decoding and sending CW messages is suitable. An example of such programs for platform OS is CW Decoder, CwType, etc. Programming can be performed on the non-platform OS, that is on the operating system, which does not execute RTOS at the moment. For this, such programs should be run in the same network segment with a platform OS, which RTOS is initiated on.