KR20140050123A - An apparatus for recording rf data and the method thereof - Google Patents

Abstract

The present invention relates to an RF data storage method and a device thereof. The present invention allows more efficient use of limited storage space by selectively recording RF data input in a specific section at the time when certain events such as a trigger signal occur when the RF data storage device records the RF data. The present invention allows efficient use of finite storage space by selectively deleting the RF data which is less important according to the priority and securing the storage space when the storage space is insufficient. The present invention improves the analysis effectiveness of an RF signal by selectively storing the RF data only related to RF signal analysis and shortening the time needed to search the RF data when analyzing the RF signal. [Reference numerals] (110) Down converter; (120) A/D converter; (140) D/A converter; (150) Up converter; (160) Processor; (170) RAM; (180) Storage; (200) External I/F; (AA) RF signal; (BB,CC) RF data; (DD) Recording; (EE) Replay; (FF) Bus; (GG) RF signal

Description

FIELD OF THE INVENTION [0001] The present invention relates to an RF data storage device,

[0001] The present invention relates to an RF data storage device and a method thereof, which can capture an RF signal and convert it into a digital signal, record it in a memory such as a hard disk, and reproduce it as needed, The present invention relates to a storage device for RF data and a method for efficiently using a limited storage capacity of the storage in an RF data storage device.

The RF data storage device according to the present invention is not limited to the specific types of signals included in a radio frequency (RF) signal (such as broadcasting signals of various bands, Global Positioning System (GPS), Electro Magnetic (EM) (Or recording) an RF signal of a specific band selectively, or an entire RF signal belonging to a certain range, converting the RF signal into a digital signal, and then storing (or recording) the RF signal in a memory such as a hard disk. In some cases, the RF data storage device also includes a component for performing a playback function, which is a reverse process of the storage.

For reference, the RF data storage device may also be used as an RF black box according to a specific use, and it is also called an RF data storage device because it mainly includes storing the RF signal into a digital storage device after converting the RF signal to digital, Except for the actual data, the term simply referred to as an RF storage device or an RF signal storage device is all the same.

The RF signal captured as described above can be used as a useful data in a relevant field by inspecting a specific RF receiving environment or examining various high frequency reception states such as medical and military fields. Therefore, since the RF data storage device stores RF data in which the RF signal is digitized, it is difficult to specify in real time how much the RF data is large and the property of the corresponding RF data. After that, it is necessary to reproduce it or perform a process of spectral analysis.

In this process, the efficiency of analysis and playback requires a means to distinguish each captured data rather than unconditionally storing the RF data on the hard disk, and also cannot store RF data in a finite storage space indefinitely. There is a need for endless recording means that can continuously store RF data that is captured even when the storage space of the RF data storage device is full, and also important data according to the importance of each stored RF data. It is necessary to find a way to effectively use the finite storage space by securing the storage space by deleting (or overwriting) first.

In addition, since there is no delimiter indicating a specific frame, a field, a picture or the like such as general digital A / V (audio / video) data in the RF data, it is necessary to separate and store the data according to an arbitrary size and time interval . It is reasonable that this distinction should be specified according to various conditions such as user's convenience of access, efficiency of storage, or convenience of implementation of system. This is different from existing digital A / V data storage devices.

However, the conventional technology for capturing and storing (or recording) and reproducing the RF data storage device, that is, the technology for capturing and storing (or recording) and reproducing the RF signal, stores RF data of a large size on a large capacity hard disk through a high speed bus technology, In this case, it is difficult to retrieve RF data of a large size, and a process of connecting and backing up a separate external hard disk is performed in the process of backing up There is a problem that the storage space of the hard disk is almost indefinitely required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an RF data recording apparatus capable of continuously recording RF data continuously captured in a limited storage space when RF data is recorded It is an object of the present invention to provide a method and a device for storing RF data in a storage device.

The present invention also relates to a method and apparatus for recording RF data to be recorded on an RF data storage device, the RF data being continuously captured, from an optimum size (storage unit) and a time The present invention also provides a method and apparatus for storing RF data in an RF data storage device capable of continuously recording an interval (storage frequency) in a limited storage space.

In addition, when recording RF data in an RF data storage device, only limited RF data is selectively recorded at a specific time point when a specific event such as a trigger signal is generated, thereby enabling a limited storage space to be more effectively used It is an object of the present invention to provide a method and apparatus for storing RF data in an RF data storage device.

Also, when recording RF data in an RF data storage device, priority is given to storing RF data having a high priority, and if the storage space is insufficient, RF data having low priority is selectively deleted, And to provide a method and apparatus for storing RF data in an RF data storage device.

An RF data storage device according to an aspect of the present invention includes RF data generation means for generating RF data for capturing an RF signal and converting the RF signal into digital data and storing the data in a storage; Storage condition determining means for determining a condition for storing the generated RF data in the storage; Recording control means for controlling the recording of RF data to the storage in accordance with the storage condition determined by the storage condition determining means; And a storage including at least one of a hard disk, a semiconductor memory, or a combination thereof, in which the RF data is stored, wherein at least one of the storage frequency, storage unit, Is determined by a schedule, a variable, or a combination thereof.

In addition, in the RF data storage device according to an aspect of the present invention, the storage is connected to a storage directly connected to the inside or outside of the RF data storage device, a local storage of an external device connected to the RF data storage device, Storage of a data server, storage of a cloud system connected to a wired or wireless network, or a combination thereof.

In the RF data storage device according to an aspect of the present invention, the recording control means may store the input RF data in a temporary storage portion of the storage, and may store at least the selected RF data in the temporary storage portion The RF data of at least one specific storage unit is copied or moved to the permanent storage unit of the storage unit to permanently store the RF data, and when the storage capacity of the temporary storage unit or the permanent storage unit is exceeded, And storing the input RF data in the storage, wherein, in accordance with the storage condition, a mark corresponding to one of at least one level for each RF data of a specific storage unit is stored in the storage, And when the storage capacity of the storage is exceeded, And stores the RF data newly input into the storage space created by the deletion, and stores the measurement data synchronized with the RF data selected by the storage condition or at least one And storing the meta data including the measurement data in the storage, wherein the input RF data is selected and stored in the storage according to the storage condition, wherein the input RF data is divided into specific storage units and temporarily stored The RF data is selected and permanently stored in the temporarily stored storage unit or temporarily stored in a continuous storage without dividing the RF data into specific storage units and then extracted and permanently stored in a specific storage unit when the RF data is selected, Storing all input RF data in the storage, And storing a mark corresponding to one of at least one level for each RF data and storing the mark in a form of a combination thereof, And if the storage space of the storage is insufficient, the RF data having the lower priority level is first deleted from the RF data to secure a storage space, and the priority level is set in the user interface or the RF data storage device The priority level designated through the program may be changed through upgrading of the software or firmware or may be adjusted through parameter adjustment by setting the operating condition of the RF data storage device independently of the program, The above- It is possible to generate and store metadata in the form of measurement data of RF data to be deleted according to the condition instead of the RF data to be deleted, and to delete or store the RF data in another storage, At least one of the measurement values included in the measurement data exceeds or falls below a preset reference value or a threshold value, and a trigger signal, a trigger signal previously designated from an external device, a trigger signal predefined at predetermined time intervals by a timer, Wherein the measurement data includes at least one of a trigger signal, a trigger signal preset in the RF data storage device, or a combination thereof, (Peak to Average Ratio), correlation, specific User-definable time-mask, spectrum, impulse noise on the time axis, user-specified spectral mask, GPS / GIS, or terrain / geographical information extracted from the navigation device , Data including A / V data, SNR, and BER extracted from a reference receiver, image data input from a camera, signals or information including SNR and BER output from a specific DUT, measurement obtained from an external instrument Information, or a combination thereof, wherein the storage condition is a condition in which only the RF data at the time when the trigger signal is generated is selected, or the RF data at the time when the trigger signal is generated and the trigger signal It is determined that the RF data is selected at a predetermined portion before and after the time point, It is determined that the RF data is selected at a unit storage interval having a relatively high frequency as the position is closer to the time point at which the trigger signal is generated, The RF data is selected at predetermined time intervals at predetermined intervals or the RF data at the trigger time is further selected when an arbitrary trigger signal is generated while selecting RF data at predetermined time intervals at each predetermined time interval. do.

According to an aspect of the present invention, there is provided a method for storing RF data, which comprises: capturing an RF signal, converting the RF signal into digital data, and generating RF data for storage in a storage including at least one of a hard disk, a semiconductor memory, A first step; A second step of determining a storage condition for storing the generated RF data in the storage; And a third step of controlling recording of RF data to the storage in accordance with the determined storage condition; Wherein at least one of the storage frequency of the RF data, the storage unit, or a combination thereof is determined by a constant, variable, or a combination thereof.

In the RF data storing method according to an aspect of the present invention, the third step may include storing the RF data in the temporary storage unit of the storage, and storing the RF data in the temporary storage unit of the storage, Further comprising a fourth step of causing the RF data of a specific storage unit to be copied or moved to the permanent storage unit of the storage for permanent storage, wherein the input RF data is selected and stored in the storage according to the storage condition, The RF data is divided into specific storage units and temporarily stored, and the RF data is selected and permanently stored in the temporarily stored storage units. Alternatively, the RF data is temporarily stored in succession without dividing the RF data into specific storage units, It is possible to extract the RF data by a specific storage unit and permanently store the RF data, Storing the RF data in at least one of at least one of a plurality of levels, storing the RF data in at least one of a plurality of levels, A trigger signal previously designated from an external device, a trigger signal previously designated at predetermined time intervals by a timer, a user interface A trigger signal, a trigger signal preset in the RF data storage device, or a combination of the trigger signal and the trigger signal, the trigger signal being generated by a user operation, Or to select only data; The RF data at the time when the trigger signal is generated and the RF data at a predetermined portion before and after the trigger signal is generated; The RF data is sorted at a unit storage interval having a relatively high frequency as the trigger signal is generated, and the RF data is selected at a relatively low frequency unit storage interval as the trigger signal is generated. ; The RF data is selected at predetermined time intervals at predetermined time intervals according to time zones or RF data at the trigger time is further selected when any trigger signal is generated while selecting RF data at predetermined time intervals at each predetermined time interval; Or a combination thereof, and determining the priority level of the RF data according to the importance of the information causing the generation of the signal related to the storage condition. And if the storage space of the storage is insufficient, deleting RF data having a low priority level from the first priority level to secure a storage space; And further comprising:

The present invention enables continuous recording of continuously captured RF data in a finite storage space when RF data is recorded in an RF data storage device, and furthermore, when a specific event such as a trigger signal is generated, In addition, when the storage space is insufficient, the low-priority RF data is selectively deleted according to the priority to save the storage space, In order to improve the analysis efficiency of RF signal by shortening the time required to search RF data when analyzing RF signal by selectively storing valid RF data related to RF signal analysis .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary diagram illustrating a configuration of an RF data storage device according to an embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus and method for generating an event trigger signal in an RF data storage device.
FIGS. 3A to 3E are diagrams illustrating a memory map for explaining various methods of storing RF data according to an embodiment of the present invention; FIG.
4 is a diagram illustrating an example of a priority level that can be set upon RF data recording in the form of a table according to an embodiment of the present invention.
5 is a flowchart illustrating a method of storing RF data according to an embodiment of the present invention.

The present invention stores RF data digitized in a storage (e.g., a hard disk) by performing A / D conversion after down-converting an RF signal to an IF signal, or performing wideband A / D conversion for directly sampling an RF signal, The RF data receiving unit may selectively receive, transmit, analyze or reproduce RF data at a desired time and place among the stored RF data to check the reception environment of the RF signal or capture / store and reproduce RF signals of a specific frequency band as a whole, A RF data storage device for enabling a precise analysis of a signal, comprising: selectively recording RF data of a specific period necessary for analysis of the RF signal in the storage space (or storage capacity) finite storage; By adding a specific mark (or identifier) to the RF data selected to have the effect, a finite storage space can be created as efficiently as possible Storing the RF data so that it can be directed to a method and an apparatus.

Hereinafter, a method of storing RF data in an RF data storage device and an embodiment of the RF data storage device according to the present invention will be described with reference to the accompanying drawings.

1 is a diagram illustrating a configuration of an RF data storage device in an RF data storage device according to an embodiment of the present invention. As shown in FIG. 1, the RF data storage device receives an RF signal of a specific frequency band and converts the RF signal into digitized RF data / Converting means 110 to 130, extracting attribute data from the RF-converted RF data and the RF signal or RF data thereof, selecting and recording RF data of a valid period for analysis of the RF signal, Processing means (160-190) for processing the selected RF data or attribute data thereof in a desired arbitrary format according to the operation of the RF data storage device, and selectively accessing the selectively recorded RF data or attribute data thereof (130 to 150) for analyzing or reproducing data, an external device interfaced with the RF data storage device, It is configured to include an external interface for inputting and outputting means 200, and combinations thereof.

The receiving / converting means 110 to 130 convert the RF signal into RF data obtained by digitizing the RF signal to capture the RF signal, and convert the RF signal received through the antenna ANT into a lower frequency band (e.g., IF A converter 120 for converting the downconverted signal into RF data digitized through A / D conversion; and an I / O converter 120 for converting the RF data into an I / (FPGA) 130 for separating signals into Q signals and converting them into baseband signals and switching the signals to the recording / processing means 160 to 190 for recording the RF data. At this time, the baseband signals separated into the I / Q signals are recorded into the storage 180 of the recording / processing means 160-190. Of course, the FEP can be replaced with a DSP or a specific processor, and if the FEP is to process digital data, it is not limited to its functions and objects to be processed. It should be noted that the present invention can be implemented by being integrated with the processor, and since the present invention is merely a conceptual illustration that only the functions corresponding to the FFP and the processor are required, various modifications are possible in the implementation Is obvious to a person skilled in the art.

The recording / processing means 160 to 190 may store attribute data extracted from the RF signal or the RF data such as minutiae point, power (field strength), trigger, spectrogram, error, impulse (time), envelope, Peak to Average Ratio (PAR), and the like, and then records the attribute data and the RF data in the storage 180. At this time, the selected RF data and the attribute data are preferably interfaced with the recording / processing means through a high-speed data transmission bus (e.g., a PCI bus). However, since the interface is not limited in its kind and method, it is natural that any method can be used.

The storage 180 is a compact, high-speed / large-capacity data storage device (or storage device) including a hard disk and a semiconductor memory, and may be an SSD (solid state drive) , A built-in or external type, a network, a cloud type, or a combination of them. In addition, if the speed of the storage 180 is not fast enough (not fast enough to be suitable for real-time processing), data is first buffered in a faster memory (RAM 170) ). ≪ / RTI >

In the present invention, the memory 170 or the storage 180 can be divided into at least one storage unit, that is, a temporary storage unit and a permanent (or long-term) storage unit, and a temporary storage unit and a permanent storage unit You can physically set it as a separate memory or storage of any kind or kind. In other words, it is sufficient to include a single or a plurality of storage areas conceptually having temporary and permanent (or long-term) concepts.

That is, the processor 160 uses the memory 170 or a part of the storage 180 as a temporary storage unit to selectively record a specific section of the RF data, and continuously inputs Thereby temporarily recording the RF data. When the storage capacity of the temporary storage unit is exceeded, the RF data (the oldest RF data) recorded unconditionally is deleted in order from the first recorded RF data, the RF data newly input into the generated storage space is recorded, RF data corresponding to preset conditions among the RF data recorded in the storage unit 180 is selected and stored in the permanent storage unit of the storage 180 (e.g., copied or transferred).

At this time, the RF data copied or transferred from the temporary storage unit to the persistent storage unit may be a partial RF signal of a specific section selected at the moment when a specific event (or trigger signal) is generated among the captured RF signals, And RF data obtained by digitizing a partial RF signal of a predetermined section selected by the user. At this time, the specific period to be recorded may vary according to the recording method proposed in the embodiment of the present invention.

Meanwhile, according to another embodiment of the present invention, the RF data stored in the temporary storage unit can be controlled to be stored according to a specific type of trigger signal, . That is, it means that more data is stored in the temporary storage unit, and some of them are stored in the permanent storage unit.

The storage 180 may further record (or store) measurement data (including attribute data or environment data) synchronized with the selected RF data according to the event (or trigger signal). The apparatus and method for storing the RF data and the attribute data or the environment data synchronized with the RF data are disclosed in Korean Patent No. 10-2012-0095348 filed on August 30, 2012 by the same applicant of the present invention, 2012-0095357. Therefore, the description of the method of extracting and storing the attribute and environment data synchronized with the RF data will be omitted in the present embodiment.

Unlike the general A / V data, the RF data handled in the present invention is such that the boundaries of the RF data or the data stream are not divided for each specific frame but continuously input in accordance with the passage of time. Therefore, It is very important to store and manage the data by synchronizing with the time information generated by the RF data storage device or received from the outside. In addition, since the reception environment of the RF signal is different for each place where the RF signal is captured, it is also very important to maintain information about the place. It is a need for synchronization of RF data to maintain consistency between at least one or more than one RF data, one or more attribute data, or a combination thereof, based on such location and time reference information. In addition, since there is no concept such as storage of frame (or field) units such as coded video or audio stream, RF data or stream must be cut and stored in an arbitrary time unit. For this reason, capturing and storing RF data It can be seen that there is a technically significant difference from storing A / V data.

Therefore, the black box for the A / V data and the black box for the RF data are distinctly different from each other, so that the terms used in the black box of the A / V data and the terms used in the RF data storage device are the same The technical features of the detailed data processing are completely different.

However, since the storage space (or storage capacity) of the storage 180 is finite and the size of the RF data is very large, the time available for recording is very limited. Accordingly, in the present invention, the storage capacity of the finite storage can be effectively managed by increasing the recordable time of the finite storage 180 and selectively recording RF data effective for analyzing the RF signal Specific apparatus and method will be described below with reference to other drawings.

The reproducing means 130 to 150 are for accessing and analyzing RF data selectively stored in the persistent storage unit of the storage 180 or for restoring / reproducing the RF data by an RF signal, (FPGA) 130 for recovering the baseband signal recorded with the I / Q signal into the RF data and switching the recovered RF data to the reproducing means, and converting the switched RF data into an analog signal And an up-converter 150 for up-converting the converted analog signal into a signal of an initially received RF band.

At this time, the upconverted signal is output to or transmitted to an external output device connected in a wire / wireless fashion. Here, the external output device is a device for receiving a signal of the same band as the received RF signal, for example, a car stereo (FM, AM, DAB etc.), a broadcast receiver (e.g., DMB, DTV), a mobile terminal , A WiFi router (e.g., a wireless modem, a wireless router), and various devices that receive wired / wireless communication and RF signals. Regarding the reproduction of the RF data, there is a method of converting RF data back into an RF signal and upconverting it, outputting it through an antenna, and then reproducing the RF data with a specific receiver, applying a specific modulation and demodulation algorithm to RF data, It is obvious that the present invention is not limited to a specific method by the present invention.

Meanwhile, the processor 160 can detect measurement data (attribute data, environmental data, etc.) of RF data as described above. In other words, the feature point, power (field strength), trigger, spectrogram, error, impulse (time), and envelope extracted from the RF signal received from the RF data storage device or RF data obtained by capturing and digitizing the RF signal, , GPS (Complementary Cumulative Distribution Function), CCD (Peak to Average Ratio), and environmental data such as geometry, GPS, and video, which represent the environment information in which the RF signal is captured. The environment data may include geographical / geographical information extracted from a device to be connected to the RF data storage device, for example, a GPS 190 connected to the inside / outside, a GIS or a navigation device, an A / V data, signal noise ratio (SNR), bit error rate (BER), image data input from a camera, signals or information including SNR and BER output from a DUT as a specific test target device, Information can be extracted. At this time, the number of environment data may be increased or decreased according to the number of devices connected to the RF data storage device.

Accordingly, the processor 160 measures at least one of the RF data or its attribute and environment data and compares it with a predetermined reference value (or a threshold value), and if the measured value exceeds the reference value (or the threshold value) And if the predetermined event occurs, the event trigger signal is generated, and the predetermined period and the predetermined unit of RF data are selected according to the event trigger signal, and the event is recorded (stored) in the permanent storage unit of the storage 180 Or stored).

The selection of the RF data to be stored is based on the storage condition, and at least one of the storage frequency, the storage unit, or the combination thereof of the RF data is determined by a constant, variable, or a combination thereof. The storage unit determines how finely divided RF data should be stored in the storage, and the storage frequency determines how often RF data divided by the storage unit is stored in the storage. Such a storage condition may be uniformly applied to the entire RF data under a predetermined condition, and the storage condition may vary variably with time. The storage condition does not exclude the case where the storage unit is equal to the total size of the storage such as storing the RF data in one file without dividing the RF data, and the storage frequency for the storage unit is only one time.

Hereinafter, a trigger signal generation method among the storage conditions for recording will be described.

2 is a diagram illustrating an example of a configuration of an apparatus for generating an event trigger signal in an RF data storage device according to an embodiment of the present invention. As shown in FIG. 2, at least one of RF data, (E.g., a reference value or a threshold value) with one of the measured values of the data measured by the measuring unit 161 and comparing the measured value with the reference value And a trigger signal output from the event detection unit 162. The event detection unit 162 detects the occurrence of an event in the event that the event has occurred, The predetermined specific period and RF data of the predetermined RF data among the RF data are selected and transferred to the permanent storage unit of the storage 180 and copied and stored And a recording control unit 163.

Here, the trigger signal (event trigger signal or internal trigger signal) is generated when any one of the attribute value and the environmental data, for example, the power suddenly exceeds a predetermined reference value (or a threshold value) Or when the average PAR of a predetermined section is measured to exceed or fall below a predetermined reference value, and the BER is measured, and control can be performed so as to occur when the BER is higher than a reference value. In addition, a spectral mask serving as a reference can be set two-dimensionally through a user interface, and a spectrum of the input RF signal can be inspected to generate a trigger signal when the spectrum mask is out of the set spectrum mask. For example, If the power is too high in the High Power amp, oscillation can occur, which can cause adjacent channels to be affected. In this case, it is possible to detect using the spectrum mask.

Of course, in addition to those listed above, an external trigger signal may be generated based on a specific external environment and input to an RF data storage device, and a recording time may be determined in an RF data storage device based on the external trigger signal. A trigger signal may be generated automatically at predetermined time intervals or may be triggered by an operation of a user input directly (or remotely using a wire / wireless communication method) through a user interface.

Hereinafter, various storing methods according to the trigger signal will be described.

For convenience of explanation, the RF data storage device according to the present embodiment divides RF data continuously input into a specific unit (for example, a specific time unit or a specific capacity unit) and stores it in the temporary storage unit, A method of sequentially deleting the first stored data and storing new input data) is assumed. At this time, the RF data is not necessarily stored in a specific unit. In the present embodiment, RF data recording means that the RF data stored in the temporary storage unit is moved or copied to the persistent storage unit, and the RF data is stored in the persistent storage unit. It can be stored in advance, and it is possible to apply the modification or change at any time by the user. Meanwhile, according to another embodiment of the present invention, the RF data stored in the temporary storage unit can be controlled to be stored according to a specific type of trigger signal, . That is, it means that more data is stored in the temporary storage unit, and some of them are stored in the permanent storage unit.

However, in the embodiment of the present invention, the RF data recording means that the RF data stored in the temporary storage unit is moved to the permanent storage unit or copied and stored.

Further, in the description of the present invention before or after the present invention, it is possible to provide a storage device capable of storing a specific RF recordable storage without providing a temporary or permanent storage section (or distinguishing temporary or permanent storage sections) The RF data may be stored in the whole part (or the entire storage area), and at the same time, a mark having at least one level may be added to the storing, managing, or controlling RF data successively. The level is assigned differently according to the importance of the storage condition, and the level is used to determine which RF data is to be erased first and the extra space to be provided if the storage space of the storage is full.

3A to 3E are diagrams illustrating memory maps for explaining various methods of storing RF data according to an embodiment of the present invention.

3A, when a trigger signal (an event trigger signal or an internal trigger signal) is generated in the event detector 162, the RF data storage device stores the RF data stored in the temporary storage unit, And stores the RF data stored in the persistent storage unit. In the RF data stored in the temporary storage unit, the RF data in which the trigger signal is not generated is not stored in the persistent storage unit. That is, recording of RF data can be skipped (hereinafter referred to as skip recording).

Also, the storage of the RF data may be stored in the storage without being distinguished from the temporary or persistent storage, and the selected RF data may be replaced with a permanent storage of the permanent data.

Also, referring to FIG. 3B, the RF data storage device may adjust a recording time to a desired time interval. For example, by generating a trigger signal at a specific time interval (e.g., every two minutes) using an internal timer, a trigger signal (hereinafter, referred to as a timer in the drawing) of the RF data stored in the temporary storage unit, And stores the selected RF data in the persistent storage unit. Like the skip recording, the RF data of the portion of the RF data stored in the temporary storage unit where the trigger signal is not generated is not stored in the persistent storage unit. Hereinafter, it is referred to as time-lapse recording in which recording and skipping are repeatedly performed at the specified time intervals as described above.

In addition, the time-lapse recording can set the recording time interval differently for each time slot. For example, recording may be performed every two minutes from 1:00 am to 12:00 noon, and recording may be performed every hour from 1:00 pm to 12:00 pm.

Also, the storage of the RF data may be stored in the storage without being distinguished from the temporary or persistent storage, and the selected RF data may be replaced with a permanent storage of the permanent data.

Referring to FIG. 3C, in the RF data storage device, as an application method of the skip recording, a certain period (for example, a time interval close to a time point at which a trigger signal is generated) is nonlinearly centered on a point at which a trigger signal is generated (Coarse-grained control) can be performed so that it is fine-grained control to record at a finely-spaced interval, and other constant intervals (for example, intervals that are temporally distant from the timing at which the trigger signal is generated) have.

For example, when it is assumed that RF data continuously input is divided into a specific unit (for example, 1 minute unit) and stored in the temporary storage unit, the RF data (4) stored at the time of trigger occurrence and the time The RF data (2, 6) closest to the time at the trigger occurrence time are stored with a slight time difference, and the time The remote RF data (# 1, # 7) is stored with more time difference. In this case, the time difference (or recording interval) is not a fixed value, but it can be adjusted to any desired value.

Also, the storage of the RF data may be stored in the storage without being distinguished from the temporary or persistent storage, and the selected RF data may be replaced with a permanent storage of the permanent data.

Referring to FIG. 3D, the RF data storage device may store RF data stored at a time point when the trigger signal is generated in the RF data stored in the temporary storage unit, and a specific period (or a specific unit) RF data can be stored in the permanent storage at once. For example, when it is assumed that RF data continuously input is divided into a specific unit (for example, 1 minute unit) and stored in the temporary storage unit, RF data stored in the temporary storage unit, 5), and RF data (1, 3, 4, 6) of a specific interval stored consecutively before and after the trigger occurrence point are stored in the permanent storage unit at a time. At this time, the specific period is not a fixed value but can be adjusted to any desired value.

Also, the storage of the RF data may be stored in the storage without being distinguished from the temporary or persistent storage, and the selected RF data may be replaced with a permanent storage of the permanent data.

Also, referring to FIG. 3E, the RF data storage device may record a combination of a skip recording method and a time-lapse recording method. For example, the RF data (1, 2, 4) stored at the trigger occurrence time is stored in the persistent storage section in accordance with the trigger signal generated at a predetermined time interval in the internal timer among the RF data continuously stored in the temporary storage section, When a trigger signal corresponding to another condition is generated, the RF data (3) stored at the trigger occurrence time is additionally stored in the persistent storage unit.

As described above, according to the present invention, when not only all RF data continuously input but also an event corresponding to a preset specific condition occurs, that is, when a trigger signal is generated according to predetermined conditions, the trigger signal is generated (I.e., RF data of an interval effective for analysis of an RF signal) at predetermined intervals before and after the point in time at which the storage space is limited, thereby efficiently managing the finite storage 180 . Also, the storage of the RF data may be stored in the storage without being distinguished from the temporary or persistent storage, and the selected RF data may be replaced with a permanent storage of the permanent data.

However, if the storage space of the storage 180 (i.e., the storage space of the persistent storage) is insufficient, the RF data storage device according to the present invention may delete some of the RF data stored in the storage 180 and store Space is secured.

However, when data of the persistent storage unit is unconditionally deleted by the endless recording method, data important for analysis of an RF signal can be deleted. Therefore, in the present invention, data having relatively low importance (data having a relatively low effectiveness for analysis of an RF signal) So that the storage space can be secured.

Hereinafter, a storage method for securing the storage space will be described.

In the present embodiment, the data (e.g., RF data, attribute data, environment data, etc.) recorded in the persistent storage unit is indexed based on information on the time and place at which the data is generated and includes files, streams, and binary data And is recorded in any format. In addition, the data of the above-mentioned format can be set to a different priority level according to the importance of the information (or information corresponding to the generation condition of the trigger signal) causing the trigger signal for recording.

The priority level may be directly designated by a user through a user interface or may be previously programmed and designated in the RF data storage device as needed. At this time, the priority level designated by the program may be changed through upgrading of software or firmware, or may be modified at any time through parameter adjustment of an environment file (e.g., a configuration file) without changing the program, There is no particular limitation in the method.

In addition, the priority level may be included in a file name, added to a header of RF data, or managed with separate index information or metadata. Naturally, the priority level and RF data must be well synchronized. Since the synchronization method is described in detail in the above-mentioned prior applications 10-2012-0095348 and 10-2012-0095357, the method described in the above-mentioned patent is used in the present invention.

In addition, the storage of the RF data is stored in the storage without being distinguished from the temporary or persistent storage, and a mark for permanently stored data is independently assigned to the selected RF data according to the priority level, Or when providing information necessary for analysis of RF data.

4 is an exemplary diagram illustrating a priority level that can be set upon RF data recording in the form of a table according to an embodiment of the present invention.

As shown in the figure, when recording RF data, that is, when RF data stored in a temporary storage unit is sorted according to predetermined conditions and stored in a persistent storage unit, at least one trigger A priority level corresponding to a condition is stored in advance in a table form (or a database), and the RF data is recorded by setting a corresponding priority level with reference to the table (or database) when RF data is recorded.

For example, among the RF data stored in the temporary storage unit, the RF data at the time of occurrence of the trigger is recorded with setting to the highest priority level (e.g., rank 1), and RF data consecutive before and after the trigger occurrence time are stored in the second priority (E.g., rank 2), and records the RF data that is not directly contiguous to the next occurrence of the trigger but closest to the next, with the third priority level (e.g., rank 3) The RF data to be recorded at a predetermined time interval is set to a fourth priority level (for example, rank 4) irrespective of the occurrence time.

Of course, the priority level is described only for convenience of explanation, and it is obvious that the priority levels can be set in more detail based on the more detailed conditions.

For reference, high priority level means high importance RF data, and low priority level means low importance RF data. That is, the RF data having a high priority level has relatively high effectiveness for analysis of an RF signal, and the RF data having a low priority level means data having relatively low effectiveness for analysis of an RF signal.

Therefore, when the RF data in the persistent storage unit is deleted in order to secure the storage space of the storage unit 180, the RF data having a lower priority level is first subjected to deletion. That is, when selecting the RF data to be deleted, the RF data having the lowest priority level is preferentially deleted by referring to the priority levels set for the respective RF data. However, if there is a large number of data with the same priority level, the RF data that has elapsed is deleted first.

Of course, it is also possible to simply record newly inputted RF data while deleting the priority level from the RF data whose priority has elapsed since the longest time. However, since this is a recording method in which storage efficiency is poor, The RF data having the large size may be deleted or stored in another storage (e.g., cloud storage, external storage, network, etc.) Connectable storage, etc.).

Hereinafter, a storage method using the RF data storage device constructed as above will be described.

FIG. 5 is a flowchart illustrating a method of storing RF data according to an embodiment of the present invention. As shown in FIG. 5, an RF data storage device converts a RF signal into a digital And generates RF data as data (S101).

The generated RF data may be stored in a temporary storage unit of the storage unit in an endless recording manner (S102).

Among the RF data stored continuously in the temporary storage unit based on storage conditions (e.g., user input, initial value setting, internal measurement, external device input, or combination thereof) generated in each recording method The RF data corresponding to the storage condition is selected in a specific storage unit and stored in the persistent storage unit (S103)

At this time, the storage unit of the RF data is divided into units including a constant or variable size, a time interval, or a combination thereof depending on the storage condition of each recording method.

That is, the present invention selectively records a section including an effective signal related to the analysis of the RF signal among continuously inputted RF data (i.e., a section including an RF signal important for analyzing the cause of the error). This is because the time at which the error is generated is the time at which the trigger signal is generated, but the RF data of the peripheral section is needed around the trigger occurrence point in order to analyze the cause of the error or the subsequent state.

Therefore, the present invention improves the efficiency of storage having a limited storage capacity by selectively recording only RF data of an interval required for analysis of RF data, and shortens the time required for searching for RF data stored in the storage in RF signal analysis, Thereby improving the analysis efficiency of the signal.

In order to achieve the above-described effects, it is necessary to accurately detect 1) the time when the error occurs (i.e., the time when the trigger signal is generated), 2) the RF data of the specific period necessary for analysis of the RF signal And 3) it is necessary to manage the storage of the more important RF data by selecting and deleting relatively less important RF data.

Therefore, in the present invention, it is configured to detect the occurrence of an error in various situations, that is, a trigger signal can be generated at the time of occurrence of an error under various error occurrence conditions, and when the occurrence of the trigger signal (Or a specific unit) corresponding to each storage condition centering on a generation time of a trigger signal generated according to a promotional condition generated in at least one preset recording method among RF data stored in the temporary storage unit RF data is selected and stored in the persistent storage unit (S103).

At this time, the priority level corresponding to the storage condition is detected in the database and set to the RF data stored in the persistent storage unit (S104).

If the used storage capacity of the persistent storage unit in which the RF data is stored exceeds a preset reference value or the remaining storage capacity (usable storage capacity) is less than the reference value, in order to secure storage capacity of the persistent storage unit, The priority level set in the data is referred to and the RF data having the lowest priority level is deleted first (S105).

At this time, if there is data set to the same priority level, it can be determined that the priority level of the long-lived RF data is lower and can be deleted first, and the attribute of the RF data to be deleted and environment data or a combination thereof Metadata can be created and stored instead, or the RF data can be transferred to another storage for storage.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, I will understand the point. Accordingly, the technical scope of the present invention should be defined by the following claims.

110: down converter 120: A / D converter (converter)
130: FPGA 140: D / A converter
150: up converter 160: processor
161: Measuring unit 162: Event detecting unit
163: recording control unit 170:
180: Storage 190: GPS
200: External I / F

Claims (21)

RF data generating means for generating RF data for capturing and converting the RF signal into digital and storing the same in storage;
Storage condition determining means for determining an encouragement condition to store the generated RF data in the storage;
Recording control means for controlling the recording of RF data to the storage in accordance with the storage condition determined by the storage condition determining means; And
A storage including at least one of a hard disk, a semiconductor memory, or a combination thereof in which the RF data is stored;
RF storage device, characterized in that at least one or more of the storage frequency of the RF data, the storage unit or a combination thereof among the storage conditions is determined by a constant, variable or a combination thereof.
The storage system according to claim 1,
Storage directly connected to the inside or outside of the RF data storage device, local storage of an external device connected to the RF data storage device, storage of a data server connected to a wired / wireless network, storage of a cloud system connected to a wired / wireless network, or a combination thereof RF data storage comprising at least any one.
The recording apparatus according to claim 1,
The RF data is stored in the temporary storage unit of the storage, and the RF data of at least one specific storage unit selected from the temporary storage unit is copied or transferred to the permanent storage unit of the storage in accordance with the storage condition for permanent storage. RF data storage device characterized in that the.
4. The recording apparatus according to claim 3,
When the storage capacity of the temporary storage unit or the persistent storage unit is exceeded, sequentially deletes the stored RF data from the first stored RF data, and stores RF data newly input into the generated storage space.
The recording apparatus according to claim 1,
Store the input RF data in the storage, and assign a mark corresponding to at least one level for each RF data of a specific storage unit according to the storage condition, and when the storage capacity of the storage is exceeded, And determining whether to delete the RF data with reference to the mark, and storing the newly input RF data in the storage space generated by the deletion.
The recording apparatus according to claim 1,
And stores the measurement data synchronized with the RF data selected by the storage condition or the metadata including the at least one measurement data in the storage.
The recording apparatus according to claim 1,
The RF data may be selected and stored in a storage according to the storage condition, and the RF data may be temporarily stored by dividing the input RF data into a specific storage unit, and the RF data may be selectively stored in the temporarily stored storage unit or permanently stored. Instead of dividing the RF data into a specific storage unit, once it is temporarily stored continuously and then the RF data is selected, the RF data is extracted and stored in a specific storage unit for permanent storage, or all the input RF data is stored in the storage and for each of the selected RF data. RF data storage device characterized in that it is stored by giving a mark corresponding to one of at least one or more levels, or at least in a combination thereof.
The recording apparatus according to claim 1,
Priority level is assigned to the RF data according to the importance of information causing a signal related to the storage condition, and if the storage space of the storage is insufficient, priority is first deleted from the RF data having a low priority level. RF data storage device characterized in that to secure.
The method of claim 8, wherein the priority level,
The priority level designated through the program may be changed through upgrading of software or firmware or may be changed by setting the operating condition of the RF data storage device independently of the program Wherein the RF data storage device is adjustable through parameter adjustment.
The method according to claim 8, wherein the recording control means,
The method may further include the step of generating metadata including measurement data of RF data to be deleted according to the storage condition and maintaining the RF data in place of the RF data to be deleted and to delete or store the RF data in another storage RF data storage device.
The method according to claim 1, wherein the storage conditions,
At least one measurement value included in the measurement data for the input RF data exceeds or falls below a preset reference value or threshold value, so that a trigger signal, a trigger signal predetermined from an external device, and a trigger predetermined by the timer at predetermined time intervals And at least one or more of a trigger signal, a trigger signal preset in the RF data storage device, or a combination thereof by a user's manipulation through a user interface.
12. The method of claim 11,
A user-definable time mask, a spectrum, an impulse noise of a time axis, a user-defined impulse noise of a user, (A / V data extracted from a reference receiver, SNR, data including BER, image data input from a camera, specific test equipment ( A signal or information including an SNR and a BER output from a DUT, measurement information obtained from an external instrument, or a combination thereof.
The method according to claim 11, wherein the storage conditions,
It is determined that only the RF data at the time when the trigger signal is generated is selected or the RF data at the time when the trigger signal is generated and the RF data are selected at a certain portion before and after the trigger signal is generated. Data storage device.
The method according to claim 11, wherein the storage conditions,
The RF data is sorted at a unit storage interval having a relatively high frequency as the trigger signal is generated, and the RF data is sorted at a unit storage interval having a relatively low frequency as the trigger signal is generated, Is determined to be < RTI ID = 0.0 > 1. < / RTI >
12. The method of claim 11,
It is determined to select RF data at a predetermined time interval at each designated time interval or to select RF data at the trigger time when an arbitrary trigger signal is generated while selecting RF data at a predetermined time interval at each predetermined time interval To the RF data storage device.
A first step of capturing and converting the RF signal into digital and generating RF data for storage in a storage including at least one of a hard disk, a semiconductor memory, or a combination thereof;
Determining a storage condition to store the generated RF data in the storage; And
A third step of controlling recording of RF data to the storage according to the determined storage condition; Including;
At least one or more of the storage frequency of the RF data, the storage unit or a combination thereof among the storage conditions is determined by a constant, variable or a combination thereof.
17. The method of claim 16,
Storing the RF data in a temporary storage unit of the storage and copying or transferring RF data of at least one or more specific storage units selected by the temporary storage unit to the persistent storage unit of the storage according to the storage condition, The method of claim 1, further comprising a fourth step.
17. The method of claim 16,
The RF data may be selected and stored in the storage according to the storage condition, and the RF data may be temporarily stored by dividing the input RF data into a specific storage unit, and the RF data may be selectively stored in the temporarily stored storage unit. Instead of dividing the RF data into a specific storage unit, once temporarily storing the RF data, and then selecting the RF data, the RF data may be extracted and stored in a specific storage unit for permanent storage, or all the input RF data may be stored in storage and the selected RF data And a fifth step of storing a mark corresponding to one of the at least one or more levels every time, or storing the mark in at least one of a combination thereof.
The method of claim 16, wherein the storage conditions,
At least one measurement value included in the measurement data for the input RF data exceeds or falls below a preset reference value or threshold value, so that a trigger signal, a trigger signal predetermined from an external device, and a trigger predetermined by the timer at predetermined time intervals At least one or more of a signal, a trigger signal, a preset trigger signal in the RF data storage device, or a combination thereof is determined by a user's manipulation through a user interface.
21. The method of claim 19,
Or to select only the RF data at the time when the trigger signal is generated;
The RF data at the time when the trigger signal is generated and the RF data at a predetermined portion before and after the trigger signal is generated;
The RF data is sorted at a unit storage interval having a relatively high frequency as the trigger signal is generated, and the RF data is selected at a relatively low frequency unit storage interval as the trigger signal is generated. ;
The RF data is selected at predetermined time intervals at predetermined time intervals according to time zones or RF data at the trigger time is further selected when any trigger signal is generated while selecting RF data at predetermined time intervals at each predetermined time interval;
Or a combination thereof. The RF data storing method according to claim 1,
17. The method of claim 16,
A sixth step of assigning a priority level to the RF data according to the importance of information causing a signal related to the storage condition; And
A seventh step of, if the storage space of the storage is insufficient, first deleting RF data having a low priority level to secure a storage space; RF data storage method further comprising.

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