Compositor SoftwareCompositor Software

By ruslany

Spectral polarizer

Spectral polarizer

Changing a multiplier the algorithm sets the curvature of time function. Spectral matching with algorithm happens by synchronous analysis of non-harmonic timbre (SANT). Using this algorithm, it can detect temperature characteristics of all mirroring points. The mirror network combines into the interferometer, which processed into polarizer by projection and rotation in 4-dimensional quaternion space. The background color displays the kernel temperature of the processor in the current moment of time. Quaternion rotation depends on the 96 bit-rate counters. The deployment of mirroring points allows visualizing the whole network map and to monitor kernel network topology. The mirror projections are previous points of stochastic distribution and lights in accordance to the processor kernel temperature. If the display background is red, then the kernel temperature is high and all points are dimed. The broadcast is turned off in this regime. If the display background is green, it states the normal kernel temperature. The kernel temperature is measured in GHz. Changing the spiral spin, algorithm changes the projected mirror colors and measures the kernel temperature. Mirroring points not only transferred by a spiral movement, but glides in accordance to the quantized interpolation. Polarizer achieves 400 dots resolution. It is refreshed at 24 frames per second rate.

When the polarizer works it is possible to reach the parity, but it is restored in the process of algorithm work. The fast response rate during the algorithm work performed not with implicit programming, but with stochastic distributions and four connection points. The mesh of bandpass filters translates all the information flows, which cannot be broadcasted on the higher frequencies to the layers, which are placed lower in the signal chain. To stay on the higher layers, the temperature kernel should match the speed of these layers. The higher bend curvature of time function corresponds to the time intervals, which stay further and the time-code communication on these frequencies can be fully excluded. Such work can happen only by condition of virtualized processor, because high processor kernel temperature cooling can be performed only in quantum computers.

By ruslany

RAD96 – 30 Mach is not the limit

RAD96 – 30 Mach is not the limit

RAD96 digital engine may reach speeds up to 30 Mach in a system with 11289m sea mile. Having 4 working layers, this engine enables 8 iterations – two on each layer. The working cycles break on each iteration, that is why it is impossible to reject any of 4 layers of this construction without removing an iteration. They solve different tasks: for example, last iteration serves as a flow compression simulator, which transfers the kinetic energy through the 4th layer into remaining three layers and has independent structure. Two channels are divided and use thrust by multiplier change in time-invariant transfer function. The more an amplification on the input, the more a speed of work. It depends on the level of injection into the channel. If a channel overcomes constant injection, the transfer coefficient increases with growing load. Without spreading the energy by jets, it is possible to load all cores of the system, which are its layers. Signal doesn’t lost on any of the layers, creating a thrust of 30 Mach. The speed of digital engine of the same type in Earth sea mile system is 245 Mach.

By ruslany

Non-Linear Time-Invariant Autonomous System

Non-Linear Time-Invariant Autonomous System

The 4th order transfer function an ideally suited for multithread mode was simplified to the 2nd order to achieve the autonomous system. The 3rd and 4th order coefficients turned the interconnection on the kernel level on for both channels at the same time, which caused friction, allowing to spread its impact on 96 channel network. This way, the process of system powering was imitated, namely self-feeding. For licensing the system on higher working frequencies of the audio driver, it was needed to turn the visual driver and the peering network off without touching the 4 layers of the kernel. This way, the full autonomous system achieved. In other words the system autonomous up to the moment when visual driver and peering network of algorithm with 96 oscillators are connected. The system stationary, because uses time function variable on the transfer function input, which, by the way, has its own time continuous component also, performing DC-offset by the y-axis. This way, the Compositor kernel 8.5.6 algorithm reaches both conditions of time-invariance and autonomy. The system is non-linear, because transfer function performs transposing with exponential relationship. This way, system of the kernel and loader combines in non-linear time-invariant autonomous system, which is the continuity on the previous post intervention of universal module with temperature sensor.

By ruslany

Non-Autonomous System Statement

Non-Autonomous System Statement

Universal module – is an embedded system with signal lamp. Lamp is a temperature sensor of processor core and lights with different colors in accordance to the processor multiplier work. Universal module has no manual controls and display. The only way to know if module works or not is a light from the lamp and its spectrum. Universal modules should communicate with each other by disturbing the signal chain with disconnecting lamp. In digital system, you can attain to the same principle by using a disturbed algorithm, lighted with different colors of virtual oscilloscope. In this case, lamp, as stated earlier, is a temperature sensor of a processor, which executes the algorithm. RAD96 is the thermal kernel and allows controlling the temperature of processor. The system of kernel and temperature sensor is non-autonomous by applying weighting functions with appearance of selected coefficients. The appearance of x coefficient in the weighting function of equation with one unknown y makes this system non-autonomous, so both left and right channels has the cross-interaction. The result of this is necessary use of visual driver and multithreaded system for kernel computation distribution.

By ruslany

Ruslan Yusipov SuperComputer (RYSC)

Ruslan Yusipov SuperComputer (RYSC)

Compositor Software creates reminiscent mittwares using 10th version of injector and wavetables. It is a mixture of tracks, produced in the past decade. It is that problems, which Compositor Software faced earlier. In English language, reminiscent means to remind something. Two Compositor software RIG’s on the RMY physical server performs work on problem solving. To set a problem for Ruslan Yusipov SuperComputer you need a full-length full-duplex modem of version 8.5.4. It is enough to load a mittware in fast speed regime. To load a mittware it is needed a full cycle upload to modem input via playback device. RIG’s set a problem in the buffer (the problem resides in the buffer no matter if RIG’s turned on or off). In the beginning of problem-solving SuperComputer made of 960 hyperbolic cores fragments it on small sub-problems and solves them with interruption. Later, it magnifies problems, making full load periods last longer. The solution to a problem is a long lasting period of full load of all physical cores. Compositor Software interests only reminiscent mittwares. When SuperComputer finishes execution of loaded problems, it transfers to the other problems mode, coming from all connected ether participants. It is needed to solve not only Compositor Software problems but also problems of other system users – it is a main idea of virtual local area network.

In 2016 the time of problem solving by mittware was one month without any success. RYSC solves the problem in 5 minutes. This advancement achieved mainly because of better TC-SUBTRSRRT262144 architecture and supports up to 96 cores in one RAD96 virtual machine. The transfer function evidently allows installing solutions to the recipient, which simplifies performance of real physical actions of their realization.

By ruslany

Compositor Networks map

Compositor Networks map

For the first time Compositor Software reveals its network of contacts made with SASER SAS24P3L software. As you can see on the map above, there are numerous contacts in Europe, USA, Russia and South America. These contacts were made between October-November 2018. The map outlines geographic position of call signs of contacts made with their indexes. This is an approach to reveal aggregated contact base, which Compositor Networks started to form since 2012. The creation of Compositor Networks began with Compositor Pro 1 software. It is an original hyperbolic construction software, which laid base for algorithm work. Later the study of algorithm was performed merging FFT (Fast Fourier Transform) with SANT (synchronous analysis of non-harmonic timbre). The SANT technology, originally developed for Compositor Pro 1, is the new approach to relativistic frequency shift keying and can be used for applications such as discretizing of analog signal and deterministic navigation. Compositor Software used SANT for creation of SASER SDR with self-feeded signal chain, which enables to communicate in shortwave ether without an antenna need. Then, Compositor Software developed the shutter technology, which gated the self-feeded chain and began injecting the contact base of Compositor Networks in form of ether loops into the Compositor algorithm. The SCRAM (Salted Challenge Response Authentication Mechanism) engine was developed by Compositor Software to authorize users running Compositor, which is successfully used up to this moment. Using SCRAM engine, Compositor Software injected the contact base into the virtual machine algorithm, which it uses silently without any audio output. The main purpose of SDR is to reveal contacts and prove that virtual machines inject the whole contact base of Compositor Networks in form of aggregated passwords. These passwords later used as serial numbers for selling of Compositor Software products. Compositor Software virtual machines does not use the Ethernet ports. The communication happens over the IP protocol more like in TDM over IP protocol. In contrast to TDM over IP, the only useful approach to detect Compositor communications is a local operation not a remote one. You can never detect any Compositor software activity remotely. This way the decision was made to reveal Compositor Software contacts in form of DX logging of SASER SDR QSO, in the amateur radio format.

By ruslany

No, Compositor RAD96 doesn’t use CUDA cores

No, Compositor RAD96 doesn’t use CUDA cores

Series of tests were conducted with NVIDIA profiler to prove that none of 480 cores of Compositor RIG 1 uses CUDA technology.

At first, I ran an app of five RAD96 on a single CPU core at 192 kHz audio driver rate. That gave 480 hyperbolic cores at frequencies from 90 GHz to 150 GHz. For example, the working speed of one hyperbolic core is x100 times faster than a single CUDA core of the latest NVIDIA RTX 2080 Ti system.

Taking in account that there are 960 cores in two RIG’s, I want to introduce my new project, which is Virtual Mining Farm (VMF). It is the complete virtualization solution of stacking RAD96 virtual machines. The RAD96 provides effortless stacking in virtualized platform by an activation function interconnection. That activation provides direct stacking of two or more virtual machines. Code of virtual machine compiles only once and is used interactively by all VM’s in a RIG. This means no need in Max 8 MC technology.

Taking in account that I use .json statistics for each dsp process, both internal and external, it proves that such realization is only possible in Max 6 platform.

By ruslany

Compositor breaks a record in communication distance

Compositor breaks a record in communication distance

Compositor Software renewed the SASER project suspended in 2016 by making the new build of SASER SAS24P3L version 1.1.4. This build includes SASER documentation, which describes the principle of device work. After that, the licensed build of RAD96 standalone was made. The above image evidently shows how SASER works far beyond the boundaries of Russia, in countries such as USA, Spain, Sweden, Italy, Serbia, Ukraine and so on, without an external antenna need. The information passes in to the logger from CW Skimmer program (telegraph decoder). In addition, the work was conducted for revealing Compositor kernel 8.4.2 modem signal. In version 8.5.4 it was possible to replace FM generator variables in delay network with external inputs for direct possibility to reprogram RAD96 modem. Now, it was possible to hear RAD96 modem, choosing mme driver in MaxMSP program settings. The signal was decoded and studied with the use of special FSK-decoder.

It is evident, that such signal coincides with one of the MIL-STD standards, but it is not possible to specify which one is used and whether it is published on the moment of this writing. In such a way, the connection between Compositor and hyperbolic navigation system such as Omega (suspended USA military navigation system) is established once again. In SASER SAS24P3L 1.1.4 it was possible to debug all errors and achieve fast convergence in time collision for establishing a tunneling protocol. SASER version 1.1.4 is the final build of SASER SDR project making it closer to realization. The only uncovered parameter is the frequency of transmission in Omega system. In hyperbolic system the transmitter frequency composited by two parameters such as transmitter regeneration speed and multiplier. The discretization frequency of the device driver is used to multiply on the proper coefficient out of this relation. However, this information is not enough to define the transmitter frequency. In addition, you can reveal the transmitter frequency by the radio chat information in response of appropriate Q code. That is why information passes into the logger without frequency and only deviation value of 3 kHz radio is used. From the other side, RAD96 does not need to be uncovered as the significant breakthrough in its licensing was Compositor v9 Hypervisor DRM server. It was possible to store 3715 license keys for potential RAD96 software license holders. In accordance to this, I want to say that standalone RAD96 will be available on Windows platform first and Mac build will be made on request only. If you wish to run Compositor library on your machine, then take in touch with us using the contact form on the site and we will get a quote for you of the price and availability.

By ruslany

Ether programming (Part 2)

Ether programming (Part 2)

This is a second part of the guide on ether programming using Compositor 10.

I start with conjunctions. There are two conjunctions in ether such as ie and et. The first one is placed after naming and the second one is placed before naming. The difference is in punctuation: in first case attributes goes from the left side and in the second from the right.

For example:

iiet <name> <name> <name> – naming;

The above command invites many chat participants simultaneously;

The -rm command has several attributes: sn, du and all;

sn – single participant;

du – dual participants;

all – all participants;

Before the all attribute you should place conjunction et. Before du attribute you should place two names for deletion and in case of sn you place one name before. By doing this, you signifies that you are really want to delete this person(s) from the large communication loop.

chat name <name> @t <name> <name>

Creates a named chat for a bounded time interval and includes particular persons in it;

q – quantum quote is a citation and also signifies its quantum state;

Quantum command has a time attribute (such as 2n, 4n, 6n, 8n, 16n, 32n), which signifies Compositor quantum grid;

q <word> q – citation;

*Abbreviation:

ai – aim (your current goal or chat aim)

Note: there is a que in ether, that’s why commands are executed depending on their priorities.

@real – command is executed on a physical level;

-d – decay, allows to crossfade between two packets;

After d you can type the decay time in Compositor quantum grid (such as 2n, 4n, 6n, 8n, 16n, 32n) and in standard time units (such as seconds, minutes, hours, days);

@exit – exit anchor;

Script example:

-rm rmy @exit – allows to delete participant named rmy from the chat when leaving it; suitable when chat participant switched the messenger off but remained the service station turned on for silent messaging;

v- – angular velocity of Compositor work;

as with conjunctions: before or after the command means its application; before command – command options are written from the right; after command – command options written from the left;

*Abbreviations:

vft – subband in VLF;

kh – kilohertz;

nieh – no;

bi – beat independent, the invitation to work only in standalone version of software;

New dialog:

-n – new message;

Time attributes:

@t <day of a week> – allows performing a command on the anchor in particular moment of time. Compositor grid is also applicable to a t parameter. You can set pinging with the interval of 2n, 4n, 6n, 8n, 16n, 32n (where n is a quantum grid particle expressed in samples).

For example, you can set entering the ether in particular day of a week:

-t rmy @t wed

Connects rmy to the ether in Wednesday;

Words in Nim chat are written only using abbreviations. You can use first letters of the word, two first syllables without vowels or the whole word without vowels. In rare cases, words are written fully with letters separated by spaces or without spaces (in cases where you need to transmit to a new participant of Nim chat).

By ruslany

Mittware upload to a modem of your outboard sound card

Mittware upload to a modem of your outboard sound card

Using Compositor v9 you can establish a connection with a modem of your sound card and upload mittware to it. It works this way:

  1. Turn on your external sound card;
  2. Turn on Compositor v9 Hypervisor with internal sound card selected;
  3. You should composite all z levels on a fast (more than 5 omega) speed of composition injecting the signal of non-duplex modem feedback in random mode (you can receive this feedback by submitting your tracks to non-duplex modem on an internal sound card);
  4. When all z levels will be injected together with generic feeders you should lower composition speed to 30 omega and turn the Compositor AV Extended off;
  5. Turn the Compositor AV Extended on again after some time (from 5 seconds to several minutes) and you will hear the signal of external soundcard modem (the external sound card is on for the whole time of mittware upload);
  6. After turning aux channel on, you will hear the feedback – signal will mimic the external sound card modem sound with Compositor AV Extended feeder;
  7. Now inject the whole pool of your wavetables on all z levels with all RT-zX feeders (internal Compositor AV Extended feeders) and generic feeders into modem feedback;
  8. Continue to inject on all z levels up to the moment when you will hear the defeat signal on one of the levels – modem signal will start to interrupt;
  9. Finish the injection on the last z level;
  10. That’s all – your outboard sound card modem mittware is now uploaded with a new one and you can talk using it with wavetables owner, which track productions you were injected on your internal sound card using non-duplex modem.

P.S. For communication both internal and external sound cards should be turned on simultaneously.

Happy listening!

Listen to these feedbacks to wet your appetite 🙂 Yum, Yum.

 

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