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Logging while drilling

Logging while drilling (LWD) is a employed in the oil and gas industry to measure petrophysical properties of geological formations, such as , , resistivity, and saturation, directly during the drilling process without interrupting operations. These measurements are obtained by integrating specialized logging tools into the bottom hole assembly (BHA) near the , where data is either transmitted in to the surface via mud pulse telemetry or stored in downhole for retrieval upon tripping out of the hole. This approach enables geoscientists and drilling engineers to evaluate quality, optimize well placement, and detect potential hazards like zones in near-real time. Well logging originated in the 1920s with early resistivity experiments by Schlumberger, but LWD specifically emerged in the 1970s, with significant advancements driven by Norwegian regulatory mandates in the 1980s that required comprehensive formation evaluation in high-risk environments. By the late 20th century, LWD had evolved from basic measurement-while-drilling (MWD) tools—focused on directional control—to sophisticated services incorporating nuclear, electromagnetic, and acoustic sensors, often powered by batteries or turbine generators within the drill string. Today, LWD tools are essential for extended-reach, horizontal, and high-angle wells, where traditional wireline logging is impractical due to borehole instability or geometry constraints. Key measurements provided by LWD include natural for lithology identification, resistivity for fluid typing and invasion profiling, and porosity for pore space assessment, and sonic velocity for mechanical properties and seismic calibration. Advanced tools also capture borehole images, formation pressure, and (NMR) data to quantify permeability and fluid types with minimal alteration from drilling fluids. Data transmission rates are typically low at 1–2 bits per second in mode using mud pulse telemetry due to the harsh downhole environment, though newer electromagnetic methods can achieve higher rates; recorded data offers higher resolution for post-drilling analysis. The primary advantages of LWD over wireline methods include reduced formation effects—since logging occurs shortly after , before significant mud filtrate penetration—and the ability to make immediate decisions for geosteering and avoidance, such as preventing kicks by monitoring equivalent circulating (ECD). In anisotropic formations common to reservoirs, LWD resistivity tools like and measurements help derive accurate horizontal and vertical resistivities, improving saturation estimates by up to 10% compared to conventional interpretations. Despite challenges like limitations and depth correlation errors from stretch (up to 5–6 meters in deep wells), LWD has become indispensable for maximizing reservoir recovery and minimizing non-productive time in modern campaigns.

Fundamentals

Definition and Principles

Logging while drilling (LWD) refers to systems and techniques designed to acquire downhole geological and petrophysical data, such as formation and saturation, while the drill string remains in the wellbore and operations continue uninterrupted. This approach allows for the collection of formation evaluation data directly during the process, minimizing downtime compared to traditional methods that require pulling the . The fundamental principles of LWD involve integrating specialized sensors into the bottom-hole assembly (BHA), typically positioned in drill collars near the , to capture measurements of formation properties as the advances. These sensors, powered by batteries or mud-powered systems, enable continuous that supports geosteering—adjusting the well trajectory to optimize intersection—and enhances characterization by providing insights into petrophysical parameters like and permeability in near-real time. The process relies on the BHA's proximity to the formation, ensuring measurements reflect unaltered conditions with minimal effects. LWD differs from (MWD), which primarily focuses on directional control and wellbore positioning parameters such as inclination and , by emphasizing formation evaluation rather than navigational data. In LWD operations, sensors detect rock properties in the immediate vicinity of the advancing bit, with acquired data transmitted to the surface using methods like mud-pulse —where pressure waves in the encode information—or electromagnetic for wireless signal propagation through the formation. This enables timely decision-making, such as trajectory corrections, without halting .

Comparison to Related Techniques

Logging while drilling (LWD) differs fundamentally from wireline logging in its operational context and execution. LWD tools are integrated into the bottomhole assembly (BHA) and acquire formation evaluation data continuously during active , enabling real-time decision-making without interrupting operations or requiring additional trips into the wellbore. In contrast, wireline logging involves halting , pulling the drill string out of the hole (a process known as tripping), and then lowering specialized tools on a wireline cable to the target depth for measurements, which can introduce significant non-productive time (NPT) and logistical challenges, particularly in highly deviated or wells where wireline conveyance may be difficult or impossible. While LWD data can be influenced by invasion and conditions, it provides timely subsurface information for geosteering and well placement, often capturing data before deep fluid invasion occurs. Wireline logging, however, typically offers higher and accuracy for certain measurements, such as density logs with precision up to 0.015 g/cm³ in clean formations compared to LWD's 0.025 g/cm³, due to better tool stabilization and post-drilling conditions. LWD also contrasts with measurement while drilling (MWD), which primarily focuses on monitoring drilling parameters and wellbore trajectory rather than detailed formation evaluation. MWD tools measure properties like direction, inclination, weight on bit, and downhole pressure to support directional control and drilling optimization, transmitting data via mud-pulse telemetry in real time. LWD, by extension, employs similar telemetry and data storage systems but incorporates more complex sensors for petrophysical logs, such as resistivity, porosity, gamma ray, and sonic velocity, to assess lithology, fluid content, and reservoir quality. Although both operate concurrently in the BHA, MWD emphasizes operational efficiency during drilling, whereas LWD targets geological interpretation, often requiring greater memory capacity for high-resolution logs downloaded post-run if real-time transmission is limited. In terms of advantages and disadvantages, LWD reduces NPT by eliminating the need for separate wireline runs, potentially saving costs—such as in one by avoiding chemical source risks and fishing operations—and enabling faster well delivery, though its data quality may be slightly lower due to dynamic environments. Wireline provides superior for static evaluations but incurs higher risks and delays, including up to 7 days of rig time in challenging scenarios. Relative to MWD, LWD adds value in formation but increases and power demands, potentially limiting rates of if not optimized. Modern bottomhole assemblies often integrate MWD and LWD into systems for comprehensive monitoring, combining directional control with petrophysical insights to enhance overall efficiency.

Historical Development

Early Concepts

The origins of logging while drilling (LWD) trace back to the foundational innovations in well logging during the 1920s, when the , Conrad and Marcel, developed the first electrical resistivity measurements for subsurface evaluation. Initially applied to surface for mineral exploration, these techniques were adapted for borehole use, culminating in the inaugural wireline electrical resistivity log on September 5, 1927, in the Pechelbronn oil field, . This static wireline method provided post-drilling formation insights but highlighted the need for real-time data acquisition during drilling to reduce operational risks and costs associated with multiple pipe trips in increasingly deep wells. From the through the , conceptual advancements and experimental efforts pursued "drilling while logging" to enable dynamic measurements, though technological constraints hindered widespread adoption. Early ideas incorporated acoustic and electrical sensing principles, with patents emerging to address integration into the . Additional experiments explored similar electrical and acoustic methods, but reliable downhole power sources and data remained elusive, limiting progress to theoretical and small-scale tests amid the high costs of and . In the 1960s and 1970s, prototypes marked key early milestones, with companies like and developing basic tools for and resistivity measurements to support formation evaluation without interrupting . These efforts were driven by the challenges of deep wells, where wireline logging risked stuck tools or lost circulation, prompting the need to minimize pipe trips. For instance, experimental detectors and resistivity sondes were integrated into bottom-hole assemblies to provide preliminary and indicators during active . A primary challenge in this era was signal transmission from the downhole environment to the surface, addressed initially through mud pulse telemetry, which was first tested in the using variations in the to encode and relay data. Early mud pulse systems suffered from low data rates, susceptibility to noise from vibrations, and over long distances, yet they represented a critical step toward viable LWD operations.

Modern Advancements

The first commercial logging-while-drilling (LWD) tool was introduced by in 1989, featuring compensated dual resistivity measurements to assess formation properties prior to the effects of drilling fluids. This innovation marked a pivotal shift from experimental prototypes to practical deployment, enabling real-time data acquisition during drilling operations, spurred by regulatory mandates in the 1980s that required comprehensive formation evaluation in high-risk environments. In the , LWD saw rapid adoption through integrated measurement-while-drilling (MWD) and LWD services, which combined directional control with formation evaluation to support the rise of horizontal and complex well trajectories in regions like the and . During the , LWD advanced with the development of high-resolution imaging tools, such as azimuthal resistivity imagers, which provided detailed borehole wall scans for enhanced formation . Azimuthal measurements became standard for geosteering, allowing precise well placement within thin reservoirs by detecting formation boundaries in multiple directions. Additionally, electromagnetic systems emerged as a replacement for traditional mud-pulse methods, offering data rates up to 12 bits per second—several times faster—and improved reliability in challenging environments. From the 2010s to 2025, LWD integrated with digital twins for predictive modeling of drilling dynamics and real-time scenario analysis, optimizing operations by simulating wellbore conditions using live data streams. Artificial intelligence enhanced real-time interpretation, with machine learning algorithms automating lithology identification and dip angle calculations from LWD datasets, reducing interpretation time from hours to minutes. Tools for high-pressure high-temperature (HPHT) wells, capable of operating at temperatures exceeding 300°F and pressures over 20,000 psi, addressed extreme environments in deepwater and unconventional plays; notable examples include Weatherford's HeatWave Extreme system introduced in 2016. Schlumberger advanced fiber-optic integration in LWD in 2021 through Optiq solutions, enabling distributed sensing for temperature and acoustic monitoring during drilling to improve data fidelity in real time. Commercially, the LWD sector shifted toward diversified service providers including and Weatherford, which expanded offerings in integrated bottom-hole assemblies and solutions. The global LWD market grew to over $5 billion by 2025, driven by demand from unconventional reservoirs such as shale plays in the Permian Basin and , where LWD enabled efficient resource extraction amid volatile oil prices.

LWD Measurements

Common Measurement Types

Logging while drilling (LWD) tools provide a suite of petrophysical and geological measurements that enable real-time evaluation of subsurface formations during drilling operations. These measurements focus on key properties such as electrical resistivity, , , natural radioactivity, and acoustic velocity, which collectively help identify , fluid content, and formation characteristics. Resistivity logging is a fundamental LWD measurement that assesses the electrical resistance of the formation to distinguish between conductive water-saturated rocks and resistive -bearing zones. It employs tools based on electromagnetic wave propagation or laterolog principles, where deep-reading measurements penetrate further into the formation to evaluate true resistivity (), while shallow-reading ones detect invasion effects from drilling fluids. These data are crucial for estimating saturation, as hydrocarbons exhibit higher resistivity than . Porosity and density measurements in LWD utilize neutron and gamma-gamma density tools to quantify the void in rocks and the bulk density of the formation, respectively. Neutron tools emit neutrons that interact with atoms, providing an estimate of influenced by fluid and matrix properties, while gamma-gamma density tools measure the scattering of gamma rays to determine , which correlates with and aids in lithology identification such as versus . Together, these measurements help differentiate porous reservoirs from compact shales and support calculations of formation compaction. Gamma ray logging detects natural gamma radiation emitted by formations, primarily from , , and in clay minerals, serving as a proxy for or clay content and thus indicating lithological variations. Acoustic logging, often via tools, measures compressional and wave slowness (transit time) to evaluate rock mechanical properties, secondary porosity from fractures, and total through empirical correlations. These acoustic data reveal formation strength and regimes, essential for geomechanical assessments. Additional LWD measurements include (NMR) for permeability estimation by analyzing fluid relaxation times and pore size distributions, azimuthal resistivity for mapping bed boundaries and structural dips through directional sensitivity, and for assessing shape and via ultrasonic or mechanical probes. These specialized types enhance detailed formation evaluation beyond basic logs. Recent advancements as of 2025 include look-ahead capabilities sensing rock properties up to 50 feet ahead of the bit for improved geosteering in horizontal wells. Typical LWD measurement suites combine , resistivity, and porosity-density logs to provide comprehensive correlation with surface seismic data and wireline logs, enabling immediate formation evaluation without interrupting . These integrated datasets are transmitted via mud pulse or electromagnetic for timely decision-making.

Tool Technologies

Logging while drilling (LWD) tools are integrated into the bottomhole assembly (BHA) of the , typically positioned 20-30 meters (65-98 feet) behind the to minimize the effects of formation invasion and cuttings on measurements. These tools consist of modular collars that house various sensors, allowing for customizable configurations based on operational needs. The collars are constructed from high-strength, non-magnetic materials such as specialized alloys designed to resist extreme vibrations, shocks, and temperatures up to 300°F (149°C), ensuring reliable performance in harsh downhole environments. Sensor technologies in LWD tools vary by measurement type but prioritize robustness for acquisition. Electromagnetic sensors for employ induction coils that generate and detect electromagnetic fields to measure formation , providing multiple depths of . Nuclear sensors utilize cesium-137 sources to emit gamma rays for measurements and neutron interactions for evaluation, enabling assessment of formation bulk properties. Acoustic sensors rely on piezoelectric transducers to emit and receive ultrasonic waves, facilitating and measurements despite noise. Power for LWD tools is supplied by either high-capacity batteries or mud-driven generators, which convert flow into electrical energy to support operation and . Durability is enhanced through shock-mounted components that can withstand axial and lateral impacts up to 1000g for 0.5 ms, half-sine wave, protecting from the rigors of rotary drilling. These features allow tools to operate continuously without failure in dynamic conditions. The evolution of LWD tools has progressed from rudimentary systems in the , which relied solely on low-rate mud-pulse for data transmission (typically 1-3 bps), to advanced configurations in the incorporating wired for enhanced up to 1 Mbps. This shift enables simultaneous transmission of multiple data streams, such as resistivity at various depths alongside gamma and pressure readings, improving during . Early tools focused on survival in downhole conditions, while modern iterations integrate digital processing and higher rates to support complex geosteering. Innovations as of 2025 include of cuttings analysis with LWD data for optimized geosteering.

Applications and Operations

Integration in Drilling

In the planning phase of logging while drilling (LWD) operations, tool selection is determined by well objectives, such as vertical exploration for broad formation evaluation or horizontal development for precise reservoir navigation. Vertical wells prioritize LWD tools focused on nuclear and resistivity measurements for lithology identification, while horizontal wells incorporate advanced azimuthal resistivity and gamma ray sensors to support geosteering and bed boundary detection. This selection ensures compatibility with expected formation properties and drilling challenges, drawing from offset well analyses to minimize risks like tool failure in abrasive environments. Bottom hole assembly (BHA) design integrates LWD tools with mud motors, drill bits, and stabilizers to optimize weight on bit and directional control. Pre-job modeling uses offset data to simulate , , and LWD responses, positioning LWD modules near the bit for timely while ensuring fatigue-resistant connections (e.g., NC-38 or larger with stress relief features). In challenging fields like the , this engineered approach reduced BHA failures and drilling time from 27 to 9.5 days per well by incorporating LWD for monitoring. During execution, LWD at the rig site enables geosteering by providing continuous formation data, allowing trajectory adjustments to maintain contact. In the Permian Basin's low-resistivity contrast sands, LWD resistivity arrays mapped bed boundaries up to several feet ahead, facilitating horizontal well placement in thin (6–11 ft) layers and increasing productive length by avoiding exits into non- rock. On-site decisions leverage the driller's display for immediate updates, integrating and resistivity logs to steer proactively without halting operations. LWD supports key operational roles, including sidetracking to access bypassed zones, anti-collision through enhanced positional accuracy, and formation pressure prediction for stability management. In sidetracking scenarios, real-time LWD and resistivity data identify faults and boundaries, as demonstrated in the Villafortuna/Trecate HPHT field (), where tools rated to 180°C guided a sidetrack 136 m above prognosis, preventing instability in depleted intervals up to 30,000 psi. For anti-collision, integrated LWD services like Halliburton's LOGIX provide alerts based on directional and formation data, reducing risks in mature fields by maintaining separation factors during complex trajectories. Formation pressure prediction via LWD sonic and resistivity transforms enables mud weight optimization; in HPHT wells, real-time updates achieved pore pressure accuracy within 0.01 SG, avoiding kicks and losses in narrow-margin environments by adjusting equivalent circulating density proactively. The overall workflow commences with pre-job modeling of offset data to forecast LWD tool responses and BHA , establishing baseline parameters for mud weight and . On-site, the driller's visualizes LWD inputs for iterative adjustments, such as inclination changes based on resistivity inversions, ensuring with geological targets while minimizing non-productive time. This iterative process, validated in appraisal wells offshore , shortened sections by 120 m through timely pressure-based decisions without exceeding limits.

Data Acquisition and Transmission

In logging while drilling (LWD), data acquisition begins with downhole sensors, such as those measuring resistivity, gamma ray, and density, which sample formation and drilling parameters at rates typically ranging from 1 to 10 Hz to capture real-time variations during drilling. Onboard processors then perform initial noise filtering to mitigate interference from drilling vibrations and environmental factors, while generating basic log curves for immediate analysis; this processing reduces raw data volume through techniques like differential pulse code modulation (DPCM), achieving compression ratios up to 50% to optimize for limited transmission bandwidth. Tool sensor outputs, including raw waveforms from electromagnetic or nuclear sources, are prioritized for compression to preserve essential petrophysical information without excessive detail. Transmission of LWD data from the downhole tool to the surface relies on several telemetry methods, each adapted to the harsh wellbore environment. Mud pulse telemetry, the most widely used technique, generates pressure waves in the drilling fluid—either positive, negative, or continuous-phase pulses—to encode data, achieving transmission rates of 1 to 10 bits per second (bps), though advanced systems can reach up to 15 bps in optimal conditions. Electromagnetic (EM) telemetry propagates low-frequency signals through the formation and drill string, offering rates up to 20 bps and suitability for non-conductive muds, but it is limited by depth and formation resistivity. Wired drill pipe telemetry, involving electrical conductors integrated into the pipe joints, provides high-speed bidirectional communication at approximately 1 Mbps, enabling detailed real-time logs, though its high cost and complexity restrict it to specialized applications. At the surface, received signals are decoded using transducers and specialized software that demodulates the telemetry stream, reconstructing logs for display on rig-site workstations accessible to petrophysicists and engineers. involves monitoring for artifacts, such as signal distortions from vibrations or noise (typically 1-20 Hz), employing adaptive filtering and transforms to suppress up to 92% of interference and ensure . Advancements in the have integrated telemetry with high-resolution storage in LWD tools, where downhole is continuously recorded for post-run retrieval via dumps, complementing limited transmission and enabling near-complete —often exceeding 95% of total acquired information—through and enhanced suppression algorithms like deep learning-based models. This hybrid approach, supported by continuous-phase frequency keying in mud pulse systems, has improved overall throughput and reliability in complex environments.

Benefits and Challenges

Advantages

Logging while drilling (LWD) enables decision-making during drilling operations, allowing geosteerers to make immediate adjustments to the well trajectory based on incoming formation data. This capability is particularly valuable in thin reservoirs, where precise well placement can maximize reservoir exposure and drainage efficiency. For instance, advanced LWD tools facilitate proactive geosteering in stacked thin sands, optimizing lateral placement to stay within target zones and enhance hydrocarbon recovery. LWD contributes to significant cost and time savings by eliminating the need for separate wireline trips after , which can significantly reduce rig time per well and associated risks such as tool sticking. In deepwater operations, this approach lowers nonproductive time (NPT) by integrating directly into the process. Furthermore, improved well placement through LWD leads to better contact, delivering a strong (ROI) via higher production rates and more efficient field development. From a safety perspective, LWD minimizes personnel exposure to hazardous environments by avoiding the deployment of wireline tools, which requires additional rig activities and increases risks during conveyance. Additionally, pressure-while-drilling () measurements provided by LWD tools enable early detection of abnormal pressures, helping to prevent blowouts and maintain . LWD delivers high-quality data by capturing formation properties in their virgin state before significant by drilling fluids, which enhances measurement accuracy compared to post-drilling wireline logs that may be affected by fluid . This pre-invasion logging preserves the integrity of petrophysical evaluations, such as and , leading to more reliable reservoir characterization in some formations.

Limitations and Solutions

One significant limitation of logging while drilling (LWD) technology is its reduced vertical compared to wireline logging methods, often limited to several inches rather than fractions of an inch, due to the variable rate of (ROP) during active . Higher ROP exacerbates this issue by decreasing density and accuracy. Solutions include the deployment of azimuthal resistivity tools, which achieve resolutions of 0.5 to 1 inch by combining focused laterolog s with multiple sensor arrays, providing detailed images even in deviated wells. Furthermore, and algorithms enhance data through upscaling and quality improvement of LWD logs, enabling better geosteering decisions. LWD tools face substantial environmental challenges, including failures from intense downhole s and extreme temperatures above 300°F (149°C), which can lead to joint , cracks, and electronic component detachment. Reliability typically holds up to 150–175°C (302–347°F), but performance degrades significantly beyond 200°C (392°F) due to inaccuracies and material stress. Since the , mitigations have focused on robust tool designs incorporating shock-resistant components, enhanced mechanical durability to combat and wear, and redundant s for , complemented by bottomhole assembly (BHA) optimizations like stabilizers and . Power and telemetry constraints further limit LWD operations, with finite battery life restricting tool runtime and mud-pulse signal attenuation hindering data rates in deep wells exceeding 20,000 feet. Acoustic systems help by transmitting data along the drillpipe, though they also suffer losses. By 2025, hybrid systems combining mud-pulse and electromagnetic have emerged as key advancements, broadening operational envelopes in challenging environments and improving transmission reliability without sole reliance on . The high cost of advanced LWD tools represents another barrier, with upfront expenses and potential losses from downhole failures ranging from $600,000 to $1 million per incident, driven by specialized components and integration needs. These expenses are mitigated through long-term service contracts offered by major providers, which bundle maintenance and deployment, alongside modular tool designs that facilitate targeted upgrades rather than complete overhauls.

References

  1. [1]
    [PDF] Logging while drilling operation - Engineering Solid Mechanics
    Jun 4, 2019 · Logging while drilling means taking measurements of the petrophysical properties of the formation. (e.g., hydrocarbon saturation, lithology) ...
  2. [2]
    [PDF] LOGGING WHILE DRILLING (LWD) IN OIL AND GAS INDUSTRY
    INTRODUCTION. Logging while drilling (LWD) is a technique of conveying well logging tools into the well borehole downhole as part of the bottom hole assembly ...
  3. [3]
    [PDF] AADE-03-NTCE-27 Advantages and Challenges of Using Logging ...
    The Logging-While-Drilling (LWD) industry is catching up quickly with wireline technology. Gamma ray, resisitivity, density/neutron/caliper, sonic, and borehole ...
  4. [4]
    Petrophysical interpretation of logging-while-drilling borehole ...
    Oct 9, 2023 · Logging-while-drilling (LWD) instruments acquire valuable in-situ measurements of rock petrophysical properties. The LWD resistivity instruments ...<|control11|><|separator|>
  5. [5]
    None
    ### Definition
  6. [6]
    Chapter 3: Measurements On Drillpipe - OnePetro
    The second term, logging while drilling (LWD), refers to measurement of the formation's petrophysical properties. Because the mechanics of MWD enabled the ...Missing: definition | Show results with:definition
  7. [7]
    Measurement while drilling (MWD) - OnePetro
    Jan 24, 2025 · Mud-pulse telemetry is the standard method in commercial MWD and logging while drilling (LWD) systems. Acoustic systems that transmit up the ...
  8. [8]
    lwd
    ### Summary of LWD Definition and Comparisons
  9. [9]
    Formation Evaluation-While-Drilling Technology Improves Data ...
    Jun 30, 2013 · The LWD measurements compared favorably with those obtained from wireline conventional logs. Eliminating the time and expense of shipping ...<|control11|><|separator|>
  10. [10]
    MWD - Energy Glossary - SLB
    MWD tools that measure formation parameters (resistivity, porosity, sonic velocity, gamma ray) are referred to as logging-while-drilling (LWD) tools. LWD ...
  11. [11]
    OnTrak integrated MWD and LWD system - Baker Hughes
    The OnTrak integrated MWD and LWD system collects wellbore data through a suite of directional and formation evaluation measurements.Missing: comparison | Show results with:comparison
  12. [12]
    1920s - SLB
    Oct 22, 2022 · Pioneering the first of many firsts ; Year 1927, Event Doll and his team record the first electrical resistivity well log in Pechelbronn, France
  13. [13]
    Logging history rich with innovation (Hart's E&P Magazine) - SPWLA
    By lowering an electric sonde down a 1,600-ft (488- m) well in France's Pechelbronn field Sept. 5, 1927, the brothers created the first well log. This log ...
  14. [14]
    Subsurface Technology Traced Through Time - AAPG
    In 1927 a quantum change in geologists' ability to see into the earth occurred when Henri Doll and the Schlumberger brothers made the first downhole electrical ...
  15. [15]
    US1843725A - Determination of subsurface formations
    KARCHER DETERMINATION OF .SUBSURFACE FORMATIONS -mmmv A :Danna man mamma Patented Feb. 2, 1932 JOHN CLARENCE KARCHER, F MONTCLAIB, NEW JERSEY, ABSIGNOB T0 ...Missing: JC | Show results with:JC
  16. [16]
    Logging-While-Drilling A Story Of Dreams, Accomplishments, And ...
    Jun 21, 2009 · Technical and commercial successes have been part of the logging while drilling story. It started very slowly as mostly dreams in the 1920's ...
  17. [17]
    History of Petroleum Technology - SPE
    Logging While Drilling. 1983. First quantitative Logging While Drilling resistivity sensor (Halliburton). Subsalt Drilling. 1983. Subsalt drilling begins on ...
  18. [18]
    Mud Pulse MWD Systems Report - OnePetro
    Dec 1, 1981 · In various companies it was called MWD for measurement-while-drilling, LWD for logging- while-drilling, or DHLWD for downhole-logging-while- ...Missing: challenges | Show results with:challenges
  19. [19]
    High-Speed Drill String Communications Network - Intellipipe
    Largely because of this stumbling block, in the mid 1970s developers turned to a technology called "mud pulse telemetry". Mud pulse telemetry eliminates the ...
  20. [20]
    1980s - SLB
    Oct 22, 2022 · The first logging-while-drilling (LWD) tool was introduced in 1989, measuring formation properties before exposure to drilling fluids took its ...
  21. [21]
    Ten Technologies From the 1980s and 1990s That Made Today's Oil ...
    Feb 28, 2019 · In 1985, Sperry Sun led the market with its first LWD tool and the SPE paper it shared about the innovation pushed others to follow.
  22. [22]
    Real-Time Drilling Operations Centers: A History of Functionality ...
    Data acquisition services had evolved to where LWD/MWD tools provided a rich and expanding stream of real-time data allowing geoscientists and engineers to plan ...
  23. [23]
    (PDF) New Azimuthal Resistivity and High-Resolution Imager ...
    Aug 6, 2025 · A new logging-while-drilling (LWD) device provides laterolog resistivity logs and borehole images in 6-in. holes drilled with water-based mud.Missing: advancements | Show results with:advancements
  24. [24]
    Innovative EM MWD technology facilitates exploitation of ...
    Jun 30, 2010 · EM MWD systems have the advantage of no moving parts, which result in the potential for improved reliability compared to mud pulse telemetry ...
  25. [25]
    Digital Twins for Real-Time Scenario Analysis during Well ... - MDPI
    This paper defines a generalized iterative methodology for setting up a digital twin to address this shortcoming.Missing: HPHT 2020s
  26. [26]
    Logging-while-drilling formation dip interpretation based on long ...
    This study proposes a method of applying artificial intelligence in the LWD data interpretation to enhance the accuracy and efficiency of real-time data ...Missing: digital twins HPHT 2010s 2020s
  27. [27]
    What's new in well logging and formation evaluation - World Oil
    HIGH TEMPERATURE LWD. Weatherford International recently introduced the HeatWave Extreme (HEX) HPHT LWD system, specifically for deepwater applications, Fig. 1 ...
  28. [28]
    Optiq Fiber-Optic Solutions | SLB
    Aug 19, 2021 · Optiq fiber-optic solutions cover distributed acoustic sensing (DAS), distributed temperature sensing (DTS), distributed temperature gradient sensing (DTGS),
  29. [29]
    Logging While Drilling - Halliburton
    Gather real-time, high-quality data while drilling for improved subsurface insight, increased ROP, and enhanced wellbore stability.Missing: twins HPHT 2010s 2020s
  30. [30]
    https://www.halliburton.com/en/subsurface/formation-evaluation/logging-while-drilling
  31. [31]
    How Different Density-Neutron LWD Tools Response can Affect the ...
    Sep 24, 2018 · Log While Drilling (LWD) Density-Neutron allow to calculate, in real/near real time, a continuous porosity and shale volume curves.
  32. [32]
    Are the LWD Resistivity Logs Telling the Whole Story? - OnePetro
    Oct 1, 2014 · The industry standard LWD resistivity tool uses the Electromagnetic Wave Propagation principle, which measures the attenuation and phase shift ...
  33. [33]
    A High-Resolution LWD Resistivity Imaging Tool - OnePetro
    Feb 1, 2009 · An advanced logging-while-drilling (LWD) tool has been introduced that combines laterolog-type resistivity measurements, high-resolution resistivity imaging ...
  34. [34]
    Logging-While-Drilling Laterolog vs. Electromagnetic Propagation ...
    In this paper, we presents modeling and actual examples to demonstrate that the laterolog can often provide a superior resistivity measurement for formation ...
  35. [35]
    Sourceless Neutron-Density Porosity Determination: Fit-for-Purpose ...
    Oct 8, 2012 · Advances in LWD technology have enabled the neutron porosity measurement to be obtained by employing an electronic neutron generator instead of ...
  36. [36]
    Neutron Porosity and Formation Density Acquisition Without ...
    Jun 22, 2013 · A new logging-while-drilling (LWD) tool uses a pulsed neutron generator (PNG) and a suite of detectors to determine neutron porosity and ...
  37. [37]
    Improved Measurement Quality and Reliability in a Formation ...
    This paper describes a new logging-while-drilling (LWD) tool-string, which is equivalent to a wireline triple-combo. It is composed of two tools, ...Missing: common | Show results with:common
  38. [38]
    Lwd Acoustic Log Processing: Petrophysics Modeling Improves ...
    Jun 21, 2009 · The drilling process usually generates a very complex noise environment that affects the acoustic measurement in terms of signal amplitude and, ...
  39. [39]
    Azimuthally Focused LWD Sonic Logging for Shear Wave ...
    Oct 8, 2012 · An azimuthally focused LWD sonic tool has been developed to resolve shear wave anisotropy in fast formations, and provide borehole images of ...
  40. [40]
    First Successful LWD NMR T1 and T2 Measurements in ... - OnePetro
    Apr 19, 2022 · This paper provides a case study in the Najmah Shale Formation, where an operator used an LWD penta-combo system (gamma ray, electromagnetic ...
  41. [41]
    Real-Time Data-Driven Updates for Look-Ahead Lithology ...
    In particular, integrating ultradeep azimuthal resistivity measurements with seismic data reduces uncertainty (Das et al. 2019), offering precise structural ...Missing: magnetic | Show results with:magnetic
  42. [42]
    SPE-211694-MS Delivered the First Maximum Reservoir ... - OnePetro
    ... (LWD) which has included, high-resolution micro resistivity imaging, Laterolog resistivity, nuclear magnetic resonance (NMR), sonic caliper and near-bit gamma ...
  43. [43]
    A New-Generation LWD Tool With Colocated Sensors ... - OnePetro
    Summary. A new logging-while-drilling (LWD) tool that combines tradi- tional measurements of gamma ray, propagation resistivity, gamma-gamma density ...
  44. [44]
    Logging While Drilling (LWD) Formation Evaluation - SLB
    Oct 22, 2022 · Schlumberger logging-while-drilling services give you fast, high-quality data for better geosteering & formation evaluation.
  45. [45]
    OTC-30666-MS LWD Acoustic Application for Cement Bond ...
    May 4, 2020 · This technology employ piezoelectric transducers to generate acoustic waves in geological formations. The transmitter generates an omni ...
  46. [46]
    SPE International Symposium & Exhibition on Formation Damage ...
    ... shock tests (up to 500G) were completed in two weeks. ... power source (batteries and/or turbine generator) to the onboard electronics in the steering unit. ... LWD ...<|separator|>
  47. [47]
    Logging While Drilling Market Size, Share & Analysis 2030
    The Logging While Drilling (LWD) Market is expected to reach USD 4.64 billion in 2025 and grow at a CAGR of 8.41% to reach USD 6.95 billion by 2030.Missing: twins 2010s 2020s<|control11|><|separator|>
  48. [48]
    BHA Design For Oil & Gas Wells - Drilling Manual
    Mar 15, 2024 · In this article, we will examine the steps involved in designing a BHA and how drilling engineers carry out this process to achieve optimal results.
  49. [49]
    Successful Geosteering in Low Resistivity Contrast Reservoirs of the ...
    Aug 17, 2011 · Successful Geosteering in Low Resistivity Contrast Reservoirs of the Permian Basin ... Logging while drilling. Introduction. The Permian ...
  50. [50]
    https://www.denimex.us/Equipment/mwd
  51. [51]
    Case study: Hostile-environment LWD allows efficient oil recovery in ...
    Mar 12, 2009 · The following case study was taken from “High-Temperature LWD (Logging-While-Drilling) Suite Provides High-Quality Data for Correlation ...Missing: anti- collision prediction
  52. [52]
    LOGIX™ collision alert service - Halliburton
    Logging-while-drilling ... As fields become more crowded, drilling wells safely and managing high-risk anti-collision situations has become more complex.
  53. [53]
    Advancement of Drilling Hazard Prevention Practices in HPHT ...
    Oct 19, 2020 · Using real-time LWD and mud logging data, pore pressure was calculated and geomechanics model was updated while drilling. The geomechanics model ...
  54. [54]
    Real Time Pore Pressure Prediction Using LWD And Borehole ...
    Mar 1, 2011 · Real Time Pore Pressure Prediction Using LWD And Borehole Seismic Data Assists In Mitigating Risk On An Appraisal Well Offshore Malaysia ...
  55. [55]
    Logging While Drilling - an overview | ScienceDirect Topics
    The main problem that had to be overcome was the telemetric link between the surface and the sonde adjacent to the drill bit. Various techniques have been ...
  56. [56]
    A review of mud pulse telemetry signal impairments modeling and ...
    Jun 2, 2018 · This study reviews mud pulse telemetry system signal transmission challenges and current countermeasure trends.Missing: replacing | Show results with:replacing
  57. [57]
    Chapter 9 Measurement While Drilling - ScienceDirect.com
    Measurement while drilling (MWD) uses telemetry techniques like mud pulse, electromagnetic, acoustic, and hardwired, and MWD sensors to obtain downhole data.
  58. [58]
    A Review of Communication Technologies in Mud Pulse Telemetry ...
    The EM-LWD system utilizes the formation and drill string as the transmission channel and employs low-frequency electromagnetic signals as the transmission ...
  59. [59]
    Smart Wired Pipe: Drilling Field Trials - OnePetro
    Mar 4, 2019 · The smart wired pipe concept is truly innovative. It enables drilling systems automation and logging-while-drilling applications, such as ...Introduction · Business Drivers For Wired... · Field Testing
  60. [60]
    Telemetry services for drilling and reservoir insight - Halliburton
    Telemetry services transmit downhole data from measurement-while-drilling (MWD) and logging-while-drilling (LWD) tools to the surface to provide drilling ...Missing: methods | Show results with:methods
  61. [61]
    SPE-228892-MS Optimizing Geosteering in Thin, Stacked ...
    Nov 3, 2025 · This study presents an optimized geosteering methodology combining advanced real-time formation evaluation tools with a step-out well placement ...
  62. [62]
    Proxima advanced logging services | Baker Hughes
    Proxima advanced logging services give you the confidence to log in conventional or managed pressure drilling operations, and in any hole condition, with a full ...Missing: configuration placement
  63. [63]
    Real-Time High-Resolution LWD Images Used to Navigate a ...
    Mar 26, 2013 · LWD images are used to more efficiently drain the reservoir by providing the necessary information to stay in the target zone during longer ...
  64. [64]
    New Class of Logging While Drilling Tools Extends Possibilities for ...
    Oct 4, 2009 · Using the Weatherford high temperature LWD tools permitted the operator to acquire valid temperature, gamma ray and resistivity curves in a high ...
  65. [65]
    Pressure-While-Drilling Measurements To Solve Extended-Reach ...
    Jun 1, 2002 · ... stuck pipe. However, recent Alaskan experience has shown that as ... Logging while drilling (LWD) vendors were requested to provide ...Missing: percentage | Show results with:percentage
  66. [66]
    logging-while-drilling - Energy Glossary - SLB
    Explore the Energy Glossary · logging-while-drilling. 1. adj. [Drilling, Shale Gas]. The measurement of formation properties during the excavation of the hole ...
  67. [67]
    Invasion Corrected Fluid Saturations, from Standalone Consonant ...
    Mar 8, 2015 · A recently introduced comprehensive suite of consonant logging-while-drilling (LWD) nuclear measurements with linear mixing laws, is used to ...
  68. [68]
    Design, Calibration, Characterization, and Field Experience of New ...
    Sep 29, 2002 · When ROP is relatively slow, LWD logs will have better accuracy and finer vertical resolution than wireline logs. Conversely, at faster ...Missing: limitations | Show results with:limitations
  69. [69]
    Drilling and Logging Equipment Reliability in a Downhole Vibration ...
    Jun 18, 2024 · Logging-while-drilling (LWD) tools are also often a part of the BHA, to allow real-time decision-making based on the measured formation ...
  70. [70]
    (PDF) HPHT 101: What Every Engineer or Geoscientist Should ...
    Sensor accuracy decreases with increasing temperature. • LWD/MWD tools are reliable to 275°F with a clear decrease in dependability to 350°F. 1.2 Low ROP in ...
  71. [71]
    Chapter 15: Drilling-Data Acquisition - OnePetro
    LWD nuclear measurements can be performed either while drilling or while tripping. LWD rates vary because of ROP changes, but they typically range from 15 ...<|separator|>
  72. [72]
    Improving Drilling Efficiency and BHA Reliability Using Hybrid-Mode ...
    Mar 7, 2023 · The Hybrid-Mode Telemetry of MP and EM in one system widens the operational envelope and increases drilling performance covered by a single BHA.
  73. [73]
    Drilling for Miles in the Marcellus: Laterals Reach New Lengths
    Aug 7, 2018 · It's very expensive, the cost for losing just the tools was typically somewhere between $600,000 to $1 million per incident, and then you ...Missing: contracts | Show results with:contracts
  74. [74]
    SLB awarded multi-region deepwater contracts by Shell to support ...
    Jan 8, 2025 · The scope of the contracts will include digital directional drilling services and hardware, logging while drilling (LWD), surface logging ...Missing: upgrades | Show results with:upgrades