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The U.S. Cybersecurity and Infrastructure Security Agency (CISA) on Monday added a high-severity security flaw impacting Oracle WebLogic Server to its Known Exploited Vulnerabilities (KEV) Catalog, based on evidence of active exploitation. The vulnerability, CVE-2024-21182 (CVSS score: 7.5), allows an unauthenticated attacker with network access to take control of susceptible servers. It was

The U.S. Cybersecurity and Infrastructure Security Agency (CISA) on Monday added a high-severity security flaw impacting Oracle WebLogic Server to its Known Exploited Vulnerabilities (KEV) Catalog, based on evidence of active exploitation. The vulnerability, CVE-2024-21182 (CVSS score: 7.5), allows an unauthenticated attacker with network access to take control of susceptible servers. It was Ravie Lakshmananhttp://www.blogger.com/profile/[email protected]

Výběr nového televizoru není složitý. Nabídka je sice obrovská a cenové rozpětí široké, ale při dodržení jednoduchých pravidel dokáže svůj ideální televizor vybrat každý.

Microsoft is working to address a widespread service issue affecting the mail flow pipeline for Exchange Online customers across North America and Germany. [...]

Mozilla oficiálně ukázala chystaný redesign Nova. • Prvky se zakulatí, ale skoro všechny najdete na původních místech. • Vrátí se kompaktní režim a nastavení bude více členěné.

**Mozilla oficiálně ukázala chystaný redesign Nova. **Prvky se zakulatí, ale skoro všechny najdete na původních místech. **Vrátí se kompaktní režim a nastavení bude více členěné.

You remove the malware. You rotate the compromised credentials. You patch the original vulnerability and close the ticket. Two weeks later, the attacker is back.

Researchers investigating a campaign now tracked as Miasma found that more than 30 packages in Red Hat's @redhat-cloud-services npm namespace had been altered to deliver credential-stealing malware.

Multiple Instagram users had their accounts hijacked after attackers convinced Meta's AI-powered support tools that they were the legitimate owners. [...]

Apple surprised everyone with the power and performance of the M1 MacBook Air when it launched the laptop in late 2020. And more than five years later, those Macs show no sign of slowing down, handling everything users care to throw at them.

The Mac still boots almost instantly, races through daily tasks, offers battery life that puts even some newer Windows laptops to shame and, perhaps most importantly, still gives millions of users no compelling reason to upgrade. 

Why the MacBook Air is still going strong

The M1 wasn’t merely better than the Intel Macs it replaced. It delivered a dramatic step forward. Silent, fast, and with remarkable energy efficiency, these laptops have proved themselves to be more reliable and longer-lasting than almost any other notebook.

Apple has continued to deliver impressive improvements ever since the M1 Macs first appeared. The recently introduced M5 MacBook Air delivers double the multi-core and 50% better single-core performance than M1; that means it provides similar performance to the MacBook Pro of around three years ago. 

Apple Silicon has improved every single year and is now extremely powerful — so much so that Apple is about to sell 10 million units of the A-series MacBook Neo, a $599 machine with an iPhone-derived chip that delivers more performance than many mainstream users need.

Meanwhile, even when using a nearly-six-year-old MacBook Air, you still experience a fast browser, responsive Office apps, great battery life and powerful photo editing capabilities. 

To the Moon and back

At the high end of Apple’s range, you’ll find Macs so accomplished they can handle almost every imaginable professional task. It means that right now, today, Apple’s product range extends from good enough to simply amazing. 

Despite heavy marketing hype from competitors who boast of their own ARM-based competitors in similar price brackets, those PCs remain compromised in comparison, if only by their use of Windows, build quality, and overall higher running costs.

Think about it: All things being equal, if you gave a typical office worker an M1 MacBook Air and an M5 MacBook Air and asked them which models they were using, how long would it take them to figure it out? 

Sure, a highly experienced Mac user would likely know. But for a lot of people, the difference would be hard to spot because what they do on their computers just isn’t particularly demanding. 

Making people happy is good for business

Surely that’s bad for Apple’s business, right? I think not. It means Apple has created a huge population of happy Mac users who are still having a good time with the Mac they acquired in 2020. Those people tell other people about their experience, which helps evangelize the platform and can’t have hurt MacBook Neo sales this year. 

They also become more interested in other Apple products, which they can afford to invest in instead of investing in the standard PC “upgrade’”cycle. After all, if you have a platform that doesn’t need an upgrade every three years, you can spend your money on something else instead. For consumers, that might be AirPods and Apple services, while for enterprise professionals that investment might become an iPad or iPhone Pro. 

Apple doesn’t mind. It still makes bank.

The company generally finds that giving people what they want is good for business. It boosts customer satisfaction scores, reduces maintenance costs, and builds repeat customers.

That long replacement cycle delivers a second benefit, too. Apple talks extensively about sustainability. With the M-series Macs, it has achieved it. 

Sustainable technology

People use these laptops longer and get more value later when they sell them on. And when they eventually get returned for recycling, Apple can tear the machines down for parts as it works toward establishing circular manufacturing within the next four years.

The M1 MacBook Air might eventually be remembered not just as the first Apple Silicon Mac, but as representing the moment when ordinary people didn’t have to worry about performance anymore. That’s why the product refuses to die — not because it’s immortal, but because for millions of users it still does everything they need. And all the M- and A-series Macs that follow it do exactly the same thing.

One more thing, however: Intel Macs will no longer be supported by macOS 27 when it ships this year. Apple typically ends support for products around 6-7 years after it removes them from sale, so when will it end support for the M1? Potentially, not too soon.

Apple only stopped selling the M1 MacBook Air in 2024, which suggests support could continue until 2030 or 2031. So, if you bought an M1 MacBook Air in 2020, you’ve actually invested in something designed to work for you for a decade. Which PCs can truly deliver that?

No wonder the M1 MacBook Air refuses to die.

You can follow me on social media! Join me on BlueSky,  LinkedIn, Mastodon, and read The Core.

Asus jako první výrobce uvedl OLED monitor v dosud netypické kombinaci rozlišení a úhlopříčky. Jeho novinka nazvaná ROG Strix OLED XG259QWPG Ace má 24,5 palce a mřížku 1920 × 1080 px. Používá lesklý Tandem WOLED panel od LG, který oproti předchozím generacím slibuje až o 15 % vyšší jas, o 25 % ...

Russia's domestic spy agency says it has uncovered a sprawling foreign espionage operation that allegedly turned the smartphones of senior Russian officials into pocket-sized surveillance devices, though it has so far offered little in the way of evidence. In a statement Tuesday, the Federal Security Service (FSB) claimed foreign intelligence agencies implanted malware on the mobile devices of high-ranking Russian officials, allowing operators to steal data, intercept conversations, and secretly activate microphones and cameras to monitor targets and their surroundings. “This software is used to steal existing data, eavesdrop on ongoing conversations, and conduct covert acoustic and video monitoring of the environment near electronic devices, all aimed at obtaining sensitive information,” the FSB said. The agency said it had opened a criminal investigation into illegal access to computer information and the distribution of malicious software. It did not identify the alleged intelligence service responsible, disclose how many officials were affected, name the malware involved, or provide any technical indicators that would allow independent verification of the claims. As things stand, the FSB has revealed the accusation but not the proof. However, the notion that foreign intelligence agencies might target the phones of senior Russian officials is hardly farfetched. State-backed mobile surveillance campaigns have become a routine feature of modern espionage, and Moscow has spent years accusing Western intelligence services of abusing consumer technology platforms for intelligence gathering. In 2023, the FSB claimed that thousands of iPhones had been compromised in a US National Security Agency spying operation. At the time, Russian security vendor Kaspersky disclosed what became known as “Operation Triangulation”, an iPhone surveillance campaign that infected devices through iMessage. Apple denied cooperating with any government, while Kaspersky stopped short of attributing the operation to the NSA. Moscow's spy agencies are hardly strangers to offensive cyber operations themselves. Last year, the FBI warned that hackers linked to the FSB's Center 16 were exploiting a years-old Cisco vulnerability to collect configuration files from thousands of network devices associated with critical infrastructure operators. So while the FSB's latest allegations may ultimately prove accurate, they lack the technical evidence security researchers would normally expect before accepting claims of a major cyber espionage campaign. ®

AI-powered attacks and shadow AI adoption are creating new security risks inside the browser. Push Security explains why browser visibility is becoming critical for both threat detection and AI governance. [...]

Solární panely se do šesti let stanou největším zdrojem elektřiny • Servery pro AI ale kvůli nepřetržitému provozu udrží fosilní paliva • Nové čisté technologie zatím nedokážou uspokojit rostoucí poptávku

AV2 přináší lepší kompresní poměr a lepší škálovatelnost než AV1. • YouTube, Netflix nebo Instagram si už na nový formát brousí zuby. • Adopce má být velmi rychlá, předchůdce se prosazoval několik let.

CISA has ordered government agencies to secure their systems against a high-severity Oracle WebLogic Server vulnerability that was patched two years ago and is now actively exploited in attacks. [...]

Microsoft has moved to calm an increasingly noisy backlash from the security community after appearing to threaten legal action against a researcher who spent the past several weeks dumping Windows zero-days onto the internet. In a statement published on Monday, Redmond said it has "no intention to pursue action against individuals conducting or publishing security research”, a noticeably softer position than the one it adopted just days earlier when it condemned a string of public vulnerability disclosures and invoked its Digital Crimes Unit. The updated statement follows a public feud with a researcher known as Nightmare-Eclipse, who released multiple Windows zero-days along with proof-of-concept exploit code. Several of those vulnerabilities have since been exploited in the wild, turning what might have remained an obscure disclosure dispute into a much larger argument about how vendors handle security researchers. Last week, Microsoft described the publication of exploit code for unpatched flaws as "never justifiable" and warned it would work with law enforcement when criminal activity harmed customers. The statement triggered immediate criticism from parts of the security community, with researchers warning that the language risked creating a chilling effect around vulnerability research. Former Microsoft employee and security researcher Kevin Beaumont described the company's position as a "dumpster fire of its own making," while Luta Security founder Katie Moussouris, who created Microsoft's bug bounty program, told The Register the response sent mixed messages. She questioned Microsoft's decision to tout researcher compensation and recognition while responding to a researcher who claims he received neither, and argued that references to the Digital Crimes Unit made the post feel "vaguely threatening." She added that, regardless of the specifics of the dispute, Microsoft risked creating a chilling effect on other researchers considering whether to report vulnerabilities. What’s more, if Microsoft's goal was to isolate Nightmare-Eclipse, that may not be going entirely to plan. The researcher claimed over the weekend that other researchers had begun handing over vulnerabilities following Microsoft's response, including an alleged flaw dubbed "Bitskrieg" that breaks Secure Boot trust guarantees and bypasses BitLocker. Nightmare-Ecipse said the bug will be released “sometime in June”. Against that backdrop, Microsoft's Monday message read more like damage control than deterrence. "We have no intention to pursue action against individuals conducting or publishing their security research," Microsoft said, adding that legal referrals would be reserved for people engaging in malicious activity that causes harm to customers. The company also acknowledged that "some interactions have fallen short" and said it was working to learn from feedback. Notably, Microsoft stopped well short of conceding any of Nightmare-Eclipse's specific allegations. The researcher had accused Microsoft of deleting accounts used for vulnerability reporting, refusing to pay bounties, and mishandling communications through the Microsoft Security Response Center. The company has not publicly addressed those claims directly. Nobody should mistake Monday's statement for a sudden conversion to the church of full disclosure. Microsoft remains firmly of the view that researchers should report vulnerabilities privately, give vendors time to fix them, and avoid dropping working exploit code onto the internet for everyone else to play with. The problem for Redmond was that the argument had drifted well beyond the actions of one researcher. What began as a dispute over a string of Windows zero-day releases was rapidly turning into a debate about Microsoft's relationship with the security community and whether the company was comfortable invoking lawyers when that relationship soured. The updated statement looks very much like an attempt to slam the brakes on that narrative. ®

Introduction

Mexico is one of the host countries for the 2026 FIFA World Cup, with matches to be played in three major cities: Mexico City, Monterrey, and Guadalajara. These locations are expected to see a large influx of international visitors, increasing the potential security risks. Many of those risks arise from users connecting to public wireless networks.

To better understand the wireless environments that visitors may encounter, we at Kaspersky GReAT conducted a wardriving assessment in the three host cities. The aim of the study was to analyze characteristics, deployment patterns, security configurations and potential exposure risks of public Wi-Fi infrastructure in urban wireless environments.

The information collected during the assessment was used exclusively for passive observation and infrastructure analysis. No attempts were made to authenticate, intercept communications, exploit systems or interact with the detected wireless networks beyond the publicly broadcast management information.

During processing of the collected data, one step involved filtering out networks belonging to cars or cell phones categorized as mobile hotspots because they do not represent networks that can be considered part of the assessment.

Research scope

The cities included in the study have high population density and extensive wireless infrastructure deployments. We chose areas with the most prominent wireless network activity and highly concentrated public access points. We carried out wardriving research in Monterrey back in 2008, but the city’s hotspot landscape has changed since then.

We chose the following analysis areas for each of the cities:

1. Mexico City: México City Stadium, Mexico City International Airport, Zócalo, Paseo de la Reforma, Colonia Roma, La Condesa, Polanco, and Coyoacán.
2. Guadalajara: Guadalajara Stadium, Guadalajara International Airport, the city center, Zapopan, Providencia, Avenida Chapultepec, Colonia Americana, Tlaquepaque, and the area around Andares.
3. Monterrey: Monterrey Stadium, Monterrey International Airport, Fundidora Park, Cintermex Monterrey, the downtown area, Barrio Antiguo, MacroPlaza, and the San Pedro financial district.

The wireless information was collected using passive wireless reconnaissance techniques. The collected information included:

• SSID analysis and information exposure, including BSSID-derived SSIDs
• Default router configurations and ISP deployments
• Frequency and signal characteristics
• Channel congestion and spectrum usage
• Wireless security configurations, including:
  • Open and insecure wireless networks
  • WPS-enabled networks
  • Secure networks (WPA2/WPA3) with WPS enabled

We performed a wireless infrastructure analysis in Mexico City, Guadalajara, and Monterrey. We drove through the areas surrounding the World Cup stadiums, tourist zones, and other places where fan concentrations are likely to be largest. Our goal was to evaluate the security status, deployment characteristics and operational exposure of detected wireless networks.

In total, we recorded 84,588 signals with 69,473 unique Service Set Identifiers (SSIDs) in busy locations and World Cup zones across the three cities. Mexico City accounted for 61.4% of the signals, Guadalajara for 23.6%, and Monterrey for 14.8%. Approximately 82% of the signals had a single SSID (81.9%, 81.34%, and 84% respectively). Notably, they all operate under the IEEE 802.11 standard protocol.

Particular attention was given to identifying standard deployment patterns, legacy configurations, default vendor settings and information disclosure through publicly broadcast wireless identifiers.

The following sections present the results that were obtained by analyzing wireless infrastructure across the three locations.

Our findings SSID analysis and information exposure

SSID analysis was conducted to evaluate naming conventions, deployment standardization and potential information exposure.

Only a few networks (0.0047%) have an invisible SSID, meaning the names of these networks are not broadcast. Some users prefer to hide the SSID for various reasons, such as the network’s purpose, the profile of its users, internal policies, etc. In contrast, the rest of the networks maintained active SSID broadcasting.

SSID structures may unintentionally disclose operational details about internet service providers (ISPs), device manufacturers, deployment practices, organizational ownership or user identity. The repeated presence of default SSID naming patterns across the analyzed locations indicates a significant degree of infrastructure homogeneity and reuse of default wireless configurations. It may also facilitate passive infrastructure profiling by revealing standard characteristics in use.

Approximately 34% of the detected networks retained the default SSID naming conventions provided by the manufacturer or ISP, while 66% used customized identifiers.

Distribution of SSID naming conventions (download)

Several recurring SSID naming conventions associated with ISP-provided deployments were identified in the three cities. The most frequently observed patterns include identifiers such as “Club_Totalplay_WiFi”, “izzi WiFi”, and “Megacable WiFi”, which suggests extensive standardization of wireless infrastructure deployment. Additionally, we observed distinctive location-specific SSIDs in each area of analysis, such as “XXXX-Internet para Todos-CDMX” or “RED JALISCO”.

Most frequently observed SSID patterns (download)

Sequential SSID naming structures were also identified during the analysis. Patterns such as “INFINITUMXX” and “IZZI-XX” suggest automated ISP deployment and large-scale deployment strategies.

We identified 33 unique sequential naming structures among the 137 sequential SSIDs in total, representing approximately 0.16% of the detected wireless networks.

The following graph shows the top five sequential SSID patterns found in the largest number of networks:

Five most frequently observed sequential patterns (download)

Several customized SSIDs contained personal or organizational identifiers, including family names, professions, addresses or internal department references. Although personalized SSIDs may simplify local network identification for users, they may also expose sensitive information that could be useful for social engineering, physical targeting, or organizational profiling.

BSSID-derived SSID

During the analysis, multiple networks were identified that used the physical MAC address of a Wi-Fi access point (BSSID) as the visible SSID. This practice exposes hardware-level information that could facilitate vendor fingerprinting and targeted reconnaissance activities.

The organizationally unique identifier (OUI) contained in the first bytes of the BSSID identifies the equipment manufacturer. Threat actors can correlate exposed manufacturers with device-specific vulnerabilities.

BSSID-derived SSID by city (download)

Notably, we found that more than 30% of networks in all three cities reuse the MAC address as the SSID.

Default router configurations and ISP deployments

We performed wireless infrastructure profiling to identify the most common wireless equipment manufacturers and ISP deployments across the three locations.

Large-scale ISP deployments frequently use standardized wireless configurations and vendor-specific hardware platforms. Identifying dominant manufacturers and ISP naming conventions can provide insight into infrastructure and deployment practices facilitating the mapping of standardized attack surfaces.

The following figure shows the distribution of the most commonly used manufacturers.

Most frequently observed wireless equipment manufacturers (download)

The manufacturer analysis revealed a strong concentration of wireless infrastructure among a limited number of vendors. Across the three locations, Huawei Technologies, MediaTek-based devices, and other manufacturers’ equipment that is distributed through ISP channels represented a significant portion of the detected deployments. Mexico City had the most diverse infrastructure, while Monterrey and Guadalajara had a greater concentration of wireless equipment known as SOHO (small office/home office) or residential-grade hardware. The widespread presence of standard vendor platforms may facilitate infrastructure fingerprinting and large-scale targeting of known device-specific vulnerabilities.

Most frequently observed wireless equipment manufacturers across the three cities (download)

ISP deployments frequently exhibited standardized configuration patterns and recurring manufacturer identifiers. Our ISP deployment analysis revealed a high concentration of access points associated with major residential internet providers. Deployments associated with Infinitum, Totalplay and Izzi represented a substantial portion of the detected wireless infrastructure across all locations. These findings suggest a high degree of deployment standardization across networks associated with major residential internet providers. This observation was supported by the repeated presence of ISP-associated SSIDs such as “Infinitum”, “Totalplay”, and “Izzi”, combined with manufacturer identifiers frequently associated with consumer equipment, including Huawei, ZTE and other residential wireless equipment vendors.

It is important to note that, for this analysis, ISPs were primarily inferred from SSID naming conventions and manufacturer fingerprint data. A significant portion of the detected wireless networks fell into the “UNKNOWN/CUSTOM” category. This classification includes custom hotspots and networks whose naming conventions did not expose identifiable ISP-associated patterns. The findings suggest that many users and organizations (as we saw previously, approximately 66%) use custom network names, limiting direct provider attribution.

The following figure illustrates the distribution of ISP-associated wireless deployments in general.

Most frequently observed ISPs (download)

To better understand this distribution, we took the most frequently observed ISPs by city.

Most frequently observed ISPs across the three cities (download)

Frequency and signal characteristics

We also analyzed wireless signal characteristics to evaluate coverage quality, signal strength, and frequency band utilization in the three cities. In dense urban environments, signal quality and frequency spectrum distribution can affect wireless reliability, client connectivity, roaming performance, and overall network efficiency.

Signal quality analysis revealed that a substantial portion of the detected access points operated under weak or very weak signal conditions. Monterrey had the highest percentage of very weak signals, with approximately 50% of detected deployments. Similar patterns were observed in Guadalajara and Mexico City, suggesting high-density wireless environments with overlapping coverage areas. Only a limited percentage of networks were classified within the very good or excellent signal categories across the three locations.

Signal quality distribution by city (download)

Signal stability analysis revealed that most detected wireless deployments exhibited stable beacon transmission behavior. More than 96% of the detected access points across all locations were classified as stable, while only a small percentage exhibited unstable or indeterminate signal behavior.

These findings imply that the majority of the wireless infrastructure observed during the assessment corresponded to permanently deployed access points rather than transient or intermittent wireless devices.

Signal stability status (download)

Frequency band analysis revealed the strong prevalence of 2.4 GHz wireless deployments across the three locations. More than 95% of the detected wireless networks operated within the 2.4 GHz spectrum, while only a small percentage of deployments were classified under the unknown or non-standard frequency categories. This uneven distribution reflects the continued prevalence of legacy-compatible wireless infrastructure and SOHO deployments.

Frequency band utilization (download)

These findings are consistent with dense urban wireless environments with large numbers of access points in restricted spectrum allocations.

Channel congestion and spectrum usage

Next, we analyzed wireless channel utilization to evaluate frequency spectrum congestion and channel allocation patterns across the three cities. Our analysis focused on the 2.4 GHz spectrum, where channel overlap and high access point density commonly produce interference and degraded wireless performance. In densely populated wireless environments, an excessive concentration of access points on a limited number of channels can lead to co-channel interference, packet collisions, reduced throughput, and degraded network stability.

Spectrum congestion analysis revealed that the 2.4 GHz band consistently experienced elevated congestion levels across the three cities. The detailed results showed a strong concentration of deployments on channels 11, 6 and 1, which are traditionally recommended as non-overlapping channels within the 2.4 GHz spectrum. Channel 11 was the most utilized channel, accounting for 25.2% of the detected access points, followed by channel 6 with 22.5% and channel 1 with 19.5%. This distribution indicates that most wireless deployments adhere to standard channel allocation practices for 2.4 GHz Wi-Fi environments.

The following figure illustrates the overall distribution of the most frequently utilized wireless channels.

Most utilized wireless channels (download)

To further assess wireless spectrum saturation, the detected access points were grouped according to channel congestion levels: VERY_HIGH, HIGH, UNKNOWN, MEDIUM, LOW and NONE.

Mexico City had the highest proportion of heavily congested wireless channels, with approximately 7% of detected access points operating under HIGH congestion conditions. Guadalajara followed with nearly 5% of deployments categorized as HIGH congestion, while Monterrey had the lowest percentage at approximately 3.29%.

These findings suggest that wireless spectrum saturation increases proportionally with urban infrastructure density and access point concentration. Despite the presence of congested deployments, most detected access points were categorized as LOW or MEDIUM congestion, suggesting severe spectrum saturation was localized rather than uniformly distributed.

Channel congestion by city (download)

A thorough analysis of individual channel utilization revealed that channels 11, 6 and 1 consistently experienced the highest congestion levels across the three cities, which correlates with our previous findings. These channels accounted for the majority of VERY_HIGH congestion classifications, particularly within the 2.4 GHz band.

In Mexico City, channel 11 alone accounted for more than 25% of detected deployments and consistently exhibited VERY_HIGH congestion levels.

This behavior reflects the limited availability of non-overlapping channels within the 2.4 GHz spectrum and the widespread reliance on default wireless configurations.

Most congested channels by city (download)

Overall, the channel utilization analysis showed that wireless deployments are concentrated heavily within the traditional, non-overlapping 2.4 GHz channels. While this strategy reduces adjacent-channel interference, excessive access point density on the same channels can still produce significant co-channel contention and poor wireless performance in high-density urban environments.

Wireless security configurations

The next thing we evaluated was the security posture of the detected wireless networks. We analyzed the wireless security configurations advertised by access points in each of the locations.

Overall security configuration distribution

The analysis revealed that WPA2 was the dominant wireless authentication mechanism across the three cities. Mexico City had the highest WPA2 adoption rate at 81.19%, followed by Monterrey at 79.19% and Guadalajara at 77.59%.

The study found that every 6th open access point (17%) was unsafe, namely 16.5% in Mexico City, 18.5% in Guadalajara, and 17.2% in Monterrey. Open wireless deployments were consistently present across all locations, ranging between 10% and 12% of detected access points. These findings show that despite the widespread deployment of modern wireless security standards, encryption adoption remains incomplete.

Distribution of wireless authentication mechanisms across the three locations (download)

To simplify the interpretation of wireless security posture, we grouped detected networks into four categories:

• Secure (WPA2/WPA3)
• Insecure (Open/WEP)
• Weak (WPA)
• Unknown

Across the three locations, secure networks comprised most of detected deployments, accounting for approximately 82% of all access points. However, insecure open networks still account for between 10% and 12% of detected wireless infrastructure, consistent with our previous findings. It is important to mention that networks within the unknown category are not considered secure.

Mexico City had the highest percentage of secure deployments at 83.54%, while Guadalajara had the highest percentage of insecure open networks at 12.46%. Although Monterrey had the lowest percentage of insecure networks, open deployments still accounted for more than 10% of the detected access points.

Wireless security posture grouping across the three locations (download)

Although modern WPA2/WPA3 encryption standards dominate current wireless deployments, the continued presence of open and legacy WPA deployments indicates that insecure wireless configurations remain relevant from an operational standpoint. These networks may expose users to passive traffic interception, unauthorized monitoring, rogue access point attacks, and credential harvesting techniques.

WPS-enabled networks

We also analyzed Wi-Fi Protected Setup (WPS) in all the locations to evaluate additional attack surfaces. WPS is a standard feature on wireless routers that enables devices such as printers, repeaters or mobile phones to connect to a secure Wi-Fi network without manually entering a long password, typically through a PIN-based enrolled mechanism. Although WPA2 and WPA3 provide strong encryption mechanisms, the presence of WPS can introduce security weaknesses due to inherently vulnerable PIN-based enrollment methods.

By combining detections from the three locations, we found that 55% of all detected access points did not advertise WPS capabilities, leaving 45% of deployments vulnerable to WPS-based abuse. These results suggest that, despite the adoption of modern encryption standards, a significant portion of wireless infrastructure continues to expose legacy convenience features.

During the analysis, we found that Mexico City had the highest proportion of WPS-enabled networks, with 46.61% of the detected access points advertising WPS capabilities. Guadalajara was second with 43.45%, while Monterrey had the lowest proportion at 40.93%.

The percentage of detected access points advertising WPS capabilities across the three locations (download)

Almost half of the detected wireless networks in each city continued to advertise WPS, indicating that WPS prevalence is consistently high across the three cities.

Secure networks with WPS enabled

In many cases, networks classified as secure because of WPA2/WPA3 encryption still had WPS functionality enabled, which effectively increased the available attack surface.

To further assess the relationship between encryption strength and WPS exposure, we conducted a secondary analysis of secure networks (WPA2/WPA3) only. The results showed that around half of all secure deployments still exposed WPS, with the following breakdown for each city:

• Mexico City: 53.7%
• Guadalajara: 50.9%
• Monterrey: 47.5%

The proportion of secure networks with WPS enabled across the three locations (download)

These findings indicate that encryption strength alone is not enough to evaluate wireless security posture because additional protocol features, such as WPS, may still expose exploitable attack vectors.

Additional security considerations

Overall, travelers operating within dense public environments are exposed not only to insecure wireless infrastructure but also to various risks associated with digital interactions. These risks include many threats, from public USB charging systems and phishing QR codes to proximity-based protocols and exposure to shared public devices, such as interactive totems or kiosks. One particular point that should be taken into account in light of our research is the issue of rogue wireless deployments.

Rogue access points are not necessarily malicious; they may be set up accidentally by misconfiguring router settings. An entry point for potential compromise might be caused by various misconfigurations, from a weak password to an insecure protocol. However, attackers deploy such unauthorized hotspots with malicious intent to infiltrate a network. Threat actors may deploy rogue access points posing as legitimate public wireless networks in airports, hotels, cafés and tourist areas. These deployments are called “evil twins” and can trick users into connecting to attacker-controlled infrastructure capable of intercepting traffic, harvesting credentials, or performing man-in-the-middle attacks. Further risk lies in the potential compromise of local network devices or even malware distribution. Such threats complement our findings, underscoring the importance of implementing traffic encryption, using a security solution and exercising extreme caution while browsing via public networks.

Conclusion

The wardriving assessment conducted in Mexico City, Guadalajara, and Monterrey revealed that modern wireless infrastructure continues to present multiple forms of operational exposure despite the widespread adoption of WPA2 and WPA3 security standards. The analysis demonstrated that wireless environments are highly standardized in all the locations, with recurring ISP deployments, default SSID naming conventions, homogeneous manufacturer distribution, and predictable channel allocation practices observed in all three cities.

Although most of the detected networks were classified as secure under WPA2/WPA3 authentication mechanisms, a significant proportion were exposing additional attack surfaces through enabled WPS functionality, default configurations, sequential SSID structures, and infrastructure metadata disclosure. This demonstrates that encryption strength alone is insufficient for evaluating the overall security posture of wireless infrastructure. Additionally, the prevalence of open networks and legacy wireless configurations indicates that insecure deployments are still operationally relevant in all the locations.

The results also showed that wireless infrastructure is heavily concentrated within the 2.4 GHz spectrum, particularly around channels 11, 6, and 1. This leads to elevated congestion and increased co-channel interference in densely populated urban environments.

SSID analysis further revealed that publicly broadcast wireless identifiers frequently expose valuable operational information about ISPs, equipment manufacturers, deployment templates, organizational ownership, and user-defined naming practices. The identification of default ISP naming conventions, sequential SSID structures, and BSSID-derived SSIDs demonstrated that many deployments prioritize operational convenience and simplicity over exposure minimization and privacy.

The scope of the threats stemming from vulnerable wireless configurations poses serious digital exposure risks for users. The widespread presence of standard deployments, predictable SSID naming and publicly exposed infrastructure identifiers can facilitate passive reconnaissance, infrastructure fingerprinting and opportunistic targeting.

Recommendations

To minimize the risks of wireless-based exposure and the attack surface related to hotspot infrastructure, we recommend taking the following measures:

• Disable WPS functionality on wireless routers whenever possible, particularly within WPA2/WPA3 deployments.
• Avoid using default SSID naming conventions that disclose ISP providers, router manufacturers, or deployment templates.
• Refrain from using personal, organizational, or location-based identifiers in wireless network names.
• Avoid configuring SSID using BSSID or naming conventions derived from MAC addresses, as these may expose hardware fingerprinting information.
• Promote migration toward modern WPA3-capable infrastructure while removing legacy wireless protocols when operationally feasible.
• Reduce wireless congestion by optimizing channel allocation strategies and minimizing excessive dependence on the 2.4 GHz spectrum.
• Encourage adoption of 5 GHz and newer wireless technologies to reduce interference and improve spectrum efficiency.

The findings presented in this assessment emphasize the importance of combining strong wireless encryption standards, secure deployment practices, exposure minimization strategies, and user awareness to enhance the overall security posture of wireless environments.

AI-driven exploitation timelines are rapidly shrinking, and they are not going to stop shrinking. Vulnerabilities are being discovered, reproduced, and weaponized faster than ever in the history of enterprise security. As a result, the window between a vulnerability being disclosed and indiscriminate exploitation observed across the internet is now measured in hours, not days. The industry's