Раздел содержит полезную информацию и материалы для самостоятельной работы -

часто задаваемые вопросы, база знаний, софт, инструкции и гарантийная политика


Базовые знания

Обучающие материалы

Рекомендуемые источники для изучения геофизических методов.

«Малоглубинная геофизика» пособие по спецкурсу

Электротомография: аппаратура, методика и опыт применения

Научно-технический отчет по работам на геофизическом полигоне

Результаты применения малоглубинного электромагнитного профилирования на электрометрическом полигоне института нефтегазовой геологии и геофизики СО РАН

Малоглубинные наземные параметрические зондирования с помощью компактной аппаратуры

Электромагнитное профилирование компактной аппаратурой: новый подход и результаты применения

Применение геофизических методов в сельском хозяйстве

Мультидисциплинарные археолого-геофизические исследования в западной Сибири

Применение электротомографии при исследовании состояния ГТС в различных климатических условиях.

Частые вопросы

Below you could find short comparision of our products by several criteria:
— resolution:
1) SibER tools variable resolution depends of spacing between electrodes — measuring point size from 0,25 m.
2) AEMP-14 and Geovizer measuring resolution depend of frequency — measuring point size depend of step and could be interpret as start from 0,25 m3.
3) GRT-2X depth resolution — up to 2cm, measuring data point size start from 7,5 cm. GRT-81 depth resolution — up to 2mm, measuring data point size start from 3,5 cm.
— ergonomic:
1) SibER tools — need to grounding the device with electrodes into ground, additional help from 1-2 people is preferable.
2) AEMP-14 weight is about 10Kg and by one of the dimension is 2,5m. Geovizer weight is about 4,5Kg and maximum one of the dimension is 0,7m.
3) TerraZond GRT-2X has weight start from 12 Kg and for transportation usually using special cart, car or autonomous crawler.
— data visualization:
1) 2D or 3D (real, pseudo or quasi) spreading of volume resistivity and polarization for SibER tools.
2) 2D or 3D (quasi) spreading of volume apparent resistivity and signal phase shifting for AEMP-14 and Geovizer.
3) 2D — as interpolated traces per profile by 1-31 profiles and tomographic 3D (real) — as synthesis radio image.
— variant of data interpretation:
1) By changing resistivity it is possible to understand spreading of geological layers; locate of cavity and big metal objects; by value association possible to improve quality of geological information. Special software for interpretation (solving inversion model) needs.
2) Apparent resistivity and phase shifting data could help to understand position of anomaly from metals or ground disturb.
3) Easy to read radio image as 3D points or as slices with high resolution — 7.5х7.5cm for 2.5m deep with GRT-2X and 3.5×3.5 for 1m with GRT-81.
1) For deep seek needs big space and length of measuring profile, so little area could be scan only for small depth. Ground resistivity on electrodes must be not more then 3KOm — if higher salt water could help.
2) For clear interpretation — operator needs to get contrast between ground and objects. So main limitation is to seeking in low contrast ground conditions — for example better contrast for metal target will be at high resistivity condition and bad contrast to seek ground disturb (holes, cavity and dielectrics); other side will be at high conductivity ground conditions — bad contrast between ground and metal and better contrast between ground and dielectrics.
3) High frequency fades out in wet soil and water.

There are 2 ways to purchase SiberGeo products: you can make quote request directly from the Product page or buy from the local Distributors thats could be found on «Information» page from the map or useful links.

We accept standard bank transfer for all payments. Final order price in invoice include all costs except import taxes and duties, which are usually paid upon receipt of the goods. If you don’t know your country’s import terms, please contact your local customs office for the info.

If all components of order available on stock — it will normally shipped in 7-14 business day after we receive a full payment. In other case of components availability — delivery time could take 1-4 month. Exact time limits of delivery appointed in Order Invoice. Standard delivery as CPT term goes as air-freight to your nearest international airport. Delivery by DHL and FedEx usually takes 2-5 days after export registry.

We provide free of charge online basic training also as information, methodical and technical support for each customer.

We offer service on geophysical exploration supported by our specialists. For details on exploration pricing, go to «Service» page.

Видео инструкции

Работа с оборудованием, обработка и визуализация данных

KB Electrometry — supply product 2021

KB Electrometry — supply product 2018

iiSystem v.4 — быстрый экспорт и визуализация результата (QZond -> iiSystem -> 2D/3D)

Быстрый старт с аппаратурой электромагнитного профилирования «Geovizer» (QZond -> iiSystem -> 2D/3D)

3D визуализация данных индукционного профайлера (EMSControl -> iSystem -> 3D)

Обработка и визуализация данных в iiSystem (QZond -> iiSystem -> iSystem -> 2D/3D)

Визуализация карт по данным аппаратуры электромагнитного профилирования (EMSControl -> iSystem -> 2D)

Визуализация псевдоразрезов по данным аппаратуры электромагнитного профилирования (EMSControl -> iSystem -> 2D)

Software for post-processing GRT-2X data «GeoReader»

Export GRT-2X data with GeoReader to CAD format

Техническое руководство

Электроразведочная аппаратура для работ методом сопротивлений и вызванной поляризации

Руководство оператора для работы с аппаратурой серии «Скала»

Руководство по эксплуатации Скала 48K12

Руководство по эксплуатации Скала 64K15

Аппаратура электромагнитного профилирования

Инструкция по эксплуатации аппаратуры АЭМП-14

Инструкция по эксплуатации аппаратуры «Геовизер»

Аппаратура многоракурсной георадиолокации

Инструкция по эксплуатации (базовая) ГРТ-ХX

Гарантийная политика

Что покрывается гарантией:

Дефект Товара, возникший по вине производителя, вызванный использованием некачественных материалов при производстве или нарушением технологии производства и проявившийся в течение гарантийного срока в процессе эксплуатации Товара.
В период действия гарантийного срока владелец вправе потребовать устранение недостатков в товаре на безвозмездной основе, включая необходимые работы по монтажу/демонтажу данного товара.

Что не покрывается гарантией (не является неисправностью):
– естественный износ;
– неправильная эксплуатация;
– повреждения, возникшие в результате механического, химического или иного воздействия;
– несоответствие ожиданиям владельца, при условии отсутствия неисправности;
– любые иные косвенные расходы, возникшие в результате или по причине наличия брака в Товаре.

Обязанности владельца:

При возникновении неисправности/обнаружении дефекта в Продукции, необходимо обратиться к производителю Товара. Расходы по доставке Товара для осуществления гарантийного ремонта в сервисный центр и обратно владельцу осуществляется за счет владельца. Срок нахождения Товара на обслуживании по гарантии не включает время затраченное на пересылку в сервисный центр и обратно владельцу.

На момент обращения должны быть предоставлены документы, подтверждающие дату приобретения Товара.

Точная информация о гарантийном периоде и условиях гарантии на конкретный Товар указана в технических паспортах и имеет преимущественную силу.

Multi-frequency electromagnetic induction profilers

The first prototype of the EM-I profiler with 14 frequencies was assembled in 1996 (EMS#0), but because of the then crisis situation in the country, the intention to introduce and mass-produce electromagnetic scanners were left until better times. In 2001, in the laboratory of electromagnetic fields of the Institute of Petroleum Geology and Geophysics. A.A. Trofimuka SB RAS (IPGG SB RAS) a second prototype device (EMS#1) was assembled, from which the development of production and testing of the methodology began.

In 2008 was commercial release of multi-frequency electromagnetic induction profiler "NEMFIS" (EMS#05). The experience of using frequency sounding with the "NEMFIS" hardware-software complex shows that a methodological approach to the study of subsurface space to a depth of a few meters on the basis of high-quality signal reconstructions is informative and cost-effective. A comparative analysis of this technique with existing foreign technologies based on the induction methods has revealed a number of significant advantages, such as noise reduction, high resolution and sensitivity.

At 2012 - was released first "AEMP-14" (EMS#20) with completely new electronic plates and cover.
Unique properties of the device:
- the ability to obtain information in the form of geoelectric maps and profiles of the apparent resistivity values in real time on Android or Windows mobile;
- applicability in high level of electromagnetic interference conditions;
- performance in conditions of extremely low ground resistance.

First compact profiler “Geovizer” was released in 2014, it implements the induction multi-frequency sounding method, and allows contactless measuring of the underground situation. As a result of measuring, it is possible to obtain the spatial level distribution of the secondary field signal from the ground till 3 meters depth. Three-frequency EM-I profiler “Geovizer” allows profiling on any set of 3 fixed frequencies in the 12.5 – 111 kHz range, including the measuring with global coordinates automatic associating.

Multi-electrode electrical resistivity & induced polarization imaging instruments

In 2009 the core staff of the company LLC "KB Electrometry" in cooperate with the Institute of Petroleum Geology and Geophysics A.A. Trofimuka SB RAS (IPGG SB RAS) developed the "SibER 48" - multi-electrode instrument, which was designed to perform electrical exploration using resistivity and induced polarization methods with the measuring modes of electrical profiling, vertical electrical sounding, and electrical tomography. There is a switch for electromechanical relays, a generator and a selective millivoltmeter in the case. For long profiles, the “roll-up” mode is implemented with the transfer of the first segment of the multi-electrode cable of the previous arrangement to the place of the second in the next one. SibER 48 has built-in software that allows you to:
- program switching to work with 2D tomography;
- ensure the safety of data during power failures;
- disconnect any electrodes;
- provide flexible control of equipment.

Subsequently in 2014 there was developed 16x channels and 64-electrode instrument for electrical resistivity & induced polarization imaging “SibER 64”. The core of the hardware is an integrated processor unit with Linux OS. Control of the unit organises by 10 inches touch screen, which allows operator to perform all operator work without using a personal computer. Synchronization with an external PC is carried out using a standard USB cable. The internal source generator of a bipolar pulses sequence has 200W power. There is also possibility of using an external generator 1KW+. Thanks to the high-performance processor, touch screen and advanced interface, the equipment layout allows interactively programming measurement protocols, viewing, monitoring and preliminary processing of the measured data.

In 2017, KB Electrometry presented last developments - the Geovizer induction profiler and 48-electrodes 15x measuring channels electrical resistivity & induced polarization imaging instruments SibER 48K12.

In 2019, KB Electrometry brought to the market a new model 64-electrodes 15x measuring channels electrical resistivity & induced polarization imaging instruments SibER 64K15 with the ability to synchronise with an external source VP-1000M.

In January 2020, the company introduced a new version of the Xeres control software, now in the 4th version the user sets the operating voltage, indeed the current. This eliminates the occurrence of emergency situations because of a high ground resistance difference on electrodes. The logging measurement functionality and a new diagnostic module for conducting operational tests of internal nodes of the system are also added.

Multi-array ground radio imaging system

The concept of a hardware-software complex for 3D radio imaging was approved in 2006. Since 2012, the development of the multi-array ground radio imaging system "GRT-XX" (GeoRadioTomograph) has been carried out jointly with a group of specialists from the Siberian Physical-Technical Institute (TSU), programmers and specialized engineers.
In 2015, the first prototype of a 16-channel chirp signal generator that work in the 500 MHz - 2000 MHz range was created, which allows multi-angle sounding with trace digitization at 256 samples.

In April 2017 the prototype of a 32-channel generator with pre-processing on board and data transmission via Fast Ethernet (100 Mbit/s) protocol was presented.

In March 2018, at the “Georadar-2018” conference, as part of a field demonstration, a working set of GRT-23 equipment (24 antenna elements; scanning width ~ 2m) installed at the road laboratory was shown. Thanks to the integrated module based on FPGU controllers - the data processing speed was significantly increased - data collection and processing from the entire line at a measurement density of 10 cm was carried out at the speed up to 45 km/h (up to 80 km/h if using 6 measurement channels) with digitization of a trace signal on 512 samples.

In August 2018, a new version of the device was released, with an improved protocol for transmitting data via Gigabit Ethernet, providing digitization of the trace signal at 1024 samples and data collection at speeds up to 80+ km/h with a measurement density of 5 cm when using 32 antenna elements.

In July 2019, a new version of the hardware generator firmware was released, which additionally provided switching options for the measurement mode using the common midpoint method (CMP).

In August 2019, the integration of the .trz format into the GeoReader software package was completed. The results of the data processing obtained during the GPRs testing at the GC Avtodor test field in the summer of 2019, organised by the RosdorNII, demonstrate the high efficiency of the operation of software algorithms for calculating the depth section according to GOST R 58349-2019.

In January 2020, it was possible to significantly improve the quality of data due to the refinement of the antenna modules, as well as the introduction of the primary calibration technique and compensation of the hardware function.

In 2020, the company announces a new model of high frequency radio imaging system - GRT-81, designed to get three-dimensional radio images with a resolution of 15x15 mm according to plan and <2 mm in depth, in particular, to measure the thickness of the upper layer of the road surface with high accuracy, as well as to build the function of changing the relative density of the investigated environment.