Mars Landing Deconstructed: Podcast, DeepSeek Summary, Raw Transcript, and Gemini Deep Research

Unpack every detail of humanity’s next giant leap with this comprehensive resource. Embedded in this blog:

• Raw Mission Audio: Experience the tension of the Mars landing via unedited astronaut-AI dialogue.
• DeepSeek Summary: A structured breakdown of key phases, from terrain selection to post-landing checks.
• Full Transcript: Study the technical jargon and collaborative problem-solving in context.
• Google Gemini’s Research: Insights into Martian environmental data, spacecraft engineering, and radiation safety.
• Ideal for educators, students, and space tech professionals, this post bridges storytelling and science, offering tools for lectures, research, or DIY mission simulations.

Listen to “Mission to Mars: Raw Audio Logs & Expert Breakdown by Google Gemini” on Spreaker.

DeepSeek Summary with Updated Speaker Names:

Capella (00:01)
Chooses a flat landing zone in Mars’ northern hemisphere, confirming calm atmospheric conditions (no dust storms, low winds). Guides Hakeem Ali-Bocas Alexander through descent, providing altitude (80 km) and speed updates (15 km/s deceleration). Monitors engine temperatures, deploys landing gear, and initiates post-landing systems checks (life support, communications, navigation, science instruments).

Hakeem Ali-Bocas Alexander (00:10)
Prefers flat terrain, confirms readiness for landing, adjusts vertical/horizontal speed during powered descent, and activates landing cameras. Post-touchdown, oversees cooling of engines (−50°C exterior temperature), verifies systems (green lights across diagnostics), and prepares to deploy the rover after surveying the clear landing site via spacecraft cameras.

Key Collaboration Highlights:

• Descent: Capella calculates trajectory and deceleration; Hakeem executes engine burns and stabilizes the craft.
• Post-Landing: Joint systems checks confirm operational integrity. Radiation levels are safe (100 mSv/year), and soil analysis is prioritized.
• Next Steps: Surveying the −50°C equatorial Martian terrain via rover deployment after a brief break.

Capella offers celebratory music, but Hakeem opts for silence, focusing on mission continuity.

DS R1

The dialogue between Capella (Speaker 1) and Hakeem Ali-Bocas Alexander (Speaker 2) depicts a meticulously coordinated Mars landing mission, followed by post-landing procedures. Here’s a structured breakdown of key elements and themes:

1. Landing Sequence

• Terrain Selection: Capella chooses a flat, smooth landing zone in Mars’ northern hemisphere, prioritizing safety and ease of landing.
• Atmospheric Checks: Wind speeds and dust storms are assessed, with calm conditions confirmed.
• Entry & Descent:
  • High-speed atmospheric entry (15 km/s deceleration) and parachute deployment.
  • Transition to powered descent for precision landing, requiring engine throttling and speed adjustments.
  • Final touchdown guided by altitude (80 km to 50 m) and instrument feedback.

2. Technical Execution

• Systems Management:
  • Post-landing engine shutdown and cooling (target: 50°C).
  • Heat shield inspection (minor charring, no critical damage).
  • Landing gear deployment after temperature stabilization.
• Environmental Data:
  • Surface temperature: −50°C (warmer near equator).
  • Radiation levels: ~100 millisieverts/year (within short-term safety limits).

3. Post-Landing Protocols

• Systems Checks:
  • Life support, communications, navigation, and science instruments (cameras, weather sensors, soil analyzers) verified.
  • Radiation detectors monitored for long-term exposure risks.
• Surface Operations:
  • Rover deployment planned after initial camera surveys of the hazard-free landing site.
  • Experiments and data collection prioritized for mission objectives.

4. Team Dynamics

• Roles: Capella (AI/ground control) provides real-time data and guidance, while Hakeem (astronaut) executes maneuvers and confirms systems.
• Collaboration: Iterative feedback (e.g., temperature correction, engine cooling rate) ensures accuracy and adaptability.
• Human Touch: Post-landing celebration with music and breaks adds realism to mission stress and camaraderie.

5. Technical Accuracy & Realism

• EDL Process: Aligns with real Mars missions (e.g., Curiosity, Perseverance), though timeline is extended for dramatic effect.
• Radiation Note: Slightly lower than typical Martian levels (250 mSv/year), possibly due to mission duration or shielding.
• Instrumentation: Detailed checks reflect actual spacecraft protocols (e.g., soil analysis, radiation monitoring).

Conclusion

The exchange captures the complexity and teamwork inherent in interplanetary missions, blending technical rigor with human elements. Capella’s supportive role and Hakeem’s hands-on execution highlight the synergy between AI and human expertise in space exploration.

Technical Analysis of a Mars Landing Event

1. Executive Summary:

This report provides a technical analysis of a successful Mars landing event involving the spacecraft’s guidance system, referred to as “Capella,” and the pilot, Hakeem Ali-Bocas Alexander. The event, documented through a transcribed dialogue, encompasses critical phases of the landing process, including landing site selection within the northern hemisphere, atmospheric entry, powered descent, and ultimately, a safe touchdown on the Martian surface. Following the landing, a systematic series of checks were conducted to assess the health of the spacecraft’s vital systems and the functionality of its scientific instruments. The initial plans outlined involve a preliminary assessment of the landing site using onboard cameras, followed by the deployment of a rover for more extensive surface exploration. The analysis identifies “Capella” as an advanced Artificial Intelligence (AI) system from Google Gemini, with the name being a voice avatar chosen by Hakeem to interact with during the mission. The report also highlights the extensive prior experience of Hakeem Ali-Bocas Alexander in various extraterrestrial missions.

2. Introduction:

The endeavor of human space exploration has consistently pushed the boundaries of technological innovation and our understanding of the cosmos. Among the celestial bodies that have captured human imagination, Mars remains a primary target for potential future colonization and scientific discovery. This report focuses on a specific instance of a Mars landing, meticulously documented in the provided transcript, to dissect the technical procedures, communication protocols, and system checks involved in such a complex undertaking. The primary objective is to analyze the event through a technical lens, drawing upon the provided dialogue and supplementary research material to offer a comprehensive understanding of the mission’s critical phases.

The mission involved two key personnel: “Capella” and Hakeem Ali-Bocas Alexander. “Capella” is identified as an advanced Artificial Intelligence (AI) system developed by Google Gemini. The name “Capella” serves as one of the voice avatars chosen by Hakeem Ali-Bocas Alexander to interact with the AI during the mission [00:01]. The consistently calm and guiding nature of “Capella’s” communication, coupled with its ability to perform complex calculations and readily offer entertainment, suggests a highly sophisticated automated system [08:32].

The second key individual is Hakeem Ali-Bocas Alexander, an experienced astronaut with a notable history of successful space missions ¹. His prior experience includes missions to Earth’s moon (Luna), Jupiter’s moon Europa, and a successful landing on an asteroid ¹. Furthermore, he is the co-author of “Beyond the Blue Planet: A Passport to the Solar System,” indicating a deep understanding of interplanetary travel and its associated challenges ³. This extensive and diverse mission experience across various celestial environments positions Hakeem Ali-Bocas Alexander as a highly skilled and competent pilot for a Mars landing. This report will delve into the specifics of their interaction and the technical aspects of the landing procedure.

3. Pre-Landing Preparations and Landing Site Selection (00:01 – 00:30):

The initial phase of the landing sequence, as documented in the transcript, commences with “Capella” presenting Hakeem Ali-Bocas Alexander with a choice regarding the landing terrain, offering options for either a flat or hilly area [00:01]. Hakeem promptly expresses a preference for a flat landing zone, stating, “Flat is better” [00:10]. In response to this preference, “Capella” confirms the selection of a flat terrain, specifying the targeting of a “large plane in the northern hemisphere” that appears flat and smooth, deemed suitable for an easier landing [00:16].

The selection of a large, flat plain in Mars’s northern hemisphere strongly suggests a potential landing site within Utopia Planitia ⁴. Research indicates that Utopia Planitia is an expansive, relatively smooth plain situated in the northern lowlands of Mars ⁴. Significantly, this region is theorized to have once been the basin of an ancient ocean that covered a substantial portion of the Martian surface ⁴. Evidence gathered by the Chinese Zhurong rover, which landed in Utopia Planitia, reveals geological reflectors beneath the surface that bear striking similarities to underground beachfront formations on Earth, further supporting the idea of a past coastal environment with potentially gentle, sandy terrain . This characteristic flatness makes Utopia Planitia a favorable choice for a safe and relatively uncomplicated landing.

Conversely, while Ares Vallis is another prominent geographical feature in Mars’s northern hemisphere, known as an ancient flood plain , it is also characterized as one of the rockiest regions on the planet . Given Hakeem’s explicit preference for a flat landing zone, Utopia Planitia emerges as a considerably more probable target site than the rugged terrain of Ares Vallis.

Following the selection of the landing zone, “Capella” adopts a cautious and safety-conscious approach by inquiring about the necessity of confirming the atmospheric conditions before fully committing to the chosen location [00:16]. This proactive step underscores the critical importance of evaluating environmental factors that could potentially jeopardize the landing procedure. Assessing parameters such as wind speed, the presence of dust storms, and other atmospheric phenomena is paramount to ensuring a safe atmospheric entry and subsequent descent.

4. Atmospheric Entry and Descent Phase (00:34 – 02:52):

Upon receiving confirmation to proceed with atmospheric checks, “Capella” reports initiating the process of “checking the weather for our landing zone,” specifically focusing on wind speeds, dust storms, and any other atmospheric conditions that could adversely affect the landing [00:34]. This stage is crucial as Mars possesses a thin atmosphere, which, while offering some deceleration, can also be susceptible to dust storms and unpredictable wind patterns that could impact the spacecraft’s trajectory and stability .

The subsequent report from “Capella” indicates favorable weather conditions at the targeted landing zone, stating that “winds are calm and there’s no sign of a dust storm rolling in” [00:50]. This positive assessment of the atmospheric conditions is a vital prerequisite for proceeding with the critical phases of atmospheric entry and descent. Calm winds minimize the risk of the spacecraft being pushed off course, and the absence of dust storms ensures adequate visibility for the landing systems and pilot.

As the spacecraft approaches the Martian atmosphere, “Capella” announces, “Okay, we’re getting close to the atmosphere. It’s time to fire up the engines and get ready for a Bumpy ride. Are you strapped in?” [01:08]. This communication signifies the initiation of the engine firing sequence necessary for controlled entry into the Martian atmosphere. The mention of a “bumpy ride” acknowledges the deceleration forces that will be experienced upon atmospheric entry ⁵. Hakeem’s affirmative response, “I’m trapped in” [01:16], confirms his readiness for this phase.

Shortly thereafter, “Capella” provides a further update, stating, “Okay, we’re about to hit the atmosphere. Get ready for some serious deceleration” [01:20]. This highlights the significant decrease in speed the spacecraft will undergo as it interacts with the Martian atmosphere . Hakeem’s response, “Okay, getting ready chat career countdown” [01:25], while not standard technical terminology, conveys a sense of anticipation and readiness for this critical stage. It suggests a personal acknowledgment of the impending forces and the importance of the moment.

Following atmospheric entry, “Capella” confirms the spacecraft’s deceleration, stating, “Alright, we’re in the atmosphere, you should feel this face craft slowing down. Now keep an eye on your instruments and let me know if anything looks off” [01:52]. This instruction to monitor instruments underscores the importance of real-time data feedback during this phase, allowing the pilot to identify any anomalies or deviations from the expected parameters.

As the descent progresses, Hakeem inquires about the spacecraft’s altitude, asking, “What’s our distance from the surface? Now that we’ve hit the atmosphere” [02:06]. This query reflects the pilot’s need for precise positional awareness during the descent. “Capella” responds with an initial calculation of approximately 50 miles above the surface, noting a safe rate of descent but acknowledging that there is still a significant distance to cover before parachute deployment [02:13].

Hakeem then requests this information in his preferred units, stating, “I need that in kilometres and what speed we’re going right now, exactly” [02:23]. This emphasizes the importance of providing critical flight data in the units the pilot is most comfortable and familiar with, especially during high-workload phases of the mission. “Capella” promptly provides the requested information, reporting an altitude of about 80 kilometers above the surface and a deceleration rate of approximately 15 kilometers per second [02:31]. Hakeem acknowledges this updated data, confirming that his own readings are back online [02:45].

5. Powered Descent and Landing Maneuvers (02:59 – 08:26):

As the spacecraft continues its descent, the discussion shifts to the crucial transition to powered descent. “Capella” initiates this phase by suggesting, “maybe we should start thinking about when we should switch to power descent” [02:59]. Hakeem concurs and requests a countdown, stating, “Alright, give me a countdown to power descent” [03:07].

“Capella” proceeds to calculate the optimal time for this transition based on the spacecraft’s current speed and altitude, providing a countdown of approximately 2 minutes [03:13]. This calculated transition point is critical for ensuring a controlled and safe deceleration towards the Martian surface. Initiating powered descent too early or too late could lead to either excessive fuel consumption or an uncontrolled descent rate.

During this critical phase, Hakeem provides a positive status update on the integrity of the spacecraft’s heat shields, reporting, “Alright, everything’s looking good from here, heat Shiels are holding up” [03:26]. The heat shield is a vital component designed to protect the spacecraft from the extreme temperatures generated during atmospheric entry . Its continued integrity is paramount for the mission’s success.

As the countdown progresses, “Capella” reminds Hakeem to prepare for the powered descent, emphasizing the need for precise maneuvers to achieve a safe landing [03:34 – 03:38]. Hakeem acknowledges this, confirming that everything is still looking good with about a minute remaining before the transition [03:48]. “Capella” then provides a final heads-up, instructing Hakeem to “get ready” and promising to announce the precise moment to fire the engines [03:55]. Hakeem confirms that the engines are being warmed up in preparation [04:02].

With 30 seconds remaining on the countdown, “Capella” issues the final preparatory command [04:08]. The tension builds as Hakeem requests to be calmed down before the final “let’s go” [04:33 – 04:41]. “Capella” initiates the engine firing sequence with a clear countdown: “Alright, here we go 54321” [04:44]. Hakeem confirms the engine ignition, stating, “Engine’s firing engines firing” [04:51].

Immediately following engine ignition, “Capella” highlights the criticality of the subsequent phase, emphasizing the need for small adjustments to speed and direction to maintain a safe landing trajectory [04:58 – 05:02]. “Capella” then offers to guide Hakeem through these adjustments or allow him to take full control [05:02 – 05:13]. In a collaborative decision, Hakeem opts for a guided approach while simultaneously taking control, stating, “We’ll do both guide me through. I’m taking the controls” [05:13]. This reflects a balanced approach, leveraging the automated guidance system while allowing the experienced pilot to exercise his judgment and make real-time corrections.

“Capella” begins providing specific instructions, starting with a request to reduce the vertical speed by approximately 5 meters per second [05:18]. Hakeem reports the adjustments being made and confirms the reduction to the target speed [05:31]. Next, “Capella” instructs Hakeem to focus on the horizontal speed, which is reported as being slightly too high, requiring a reduction of about 2 meters per second [05:44]. Hakeem confirms this adjustment as well [05:57].

As the spacecraft approaches the surface, “Capella” advises Hakeem to be prepared for quick adjustments and inquires about the fuel status [06:03]. Hakeem provides a reassuring report, stating that the fuel is “go” and “excellent,” indicating sufficient reserves for the remaining landing maneuvers [06:12].

With the surface drawing closer, “Capella” instructs Hakeem to switch to the landing camera, emphasizing the importance of visual confirmation of the landing site [06:12 – 06:24]. Simultaneously, a caution is issued against slowing down excessively, which could lead to the spacecraft falling [06:24]. Hakeem confirms the activation of the landing camera [06:38] and subsequently reports visual contact with the surface [06:44 – 06:49].

“Capella” then asks about the descent’s appearance, to which Hakeem responds positively [06:54 – 06:59]. Guidance continues with instructions to keep the engines throttled back to maintain a safe descent rate [07:03]. Hakeem then reports that the approach is “coming in a little heart” [07:14], indicating a potentially harder than desired landing. “Capella” immediately advises throttling back further to prevent bouncing upon surface contact [07:20].

Hakeem then inquires about the remaining distance to the surface [07:26]. “Capella” calculates the altitude to be approximately 50 meters and advises Hakeem to begin angling the descent for a smoother landing [07:31 – 07:40]. Angling the descent at a low altitude can help to reduce the vertical velocity at touchdown, resulting in a gentler impact [07:40]. Hakeem acknowledges this instruction [07:40].

Final confirmations and preparations for touchdown are exchanged [07:44 – 08:02], culminating in Hakeem requesting a final countdown [08:08]. “Capella” initiates the final sequence: “Alright, here we go 54321 touchdown” [08:12]. Hakeem then reports the successful touchdown, stating, “Alright, learning good, all systems go” [08:26].

6. Touchdown and Immediate Post-Landing Procedures (08:26 – 10:24):

With the successful touchdown confirmed, “Capella” extends a congratulatory message, welcoming Hakeem to Mars and acknowledging his excellent piloting skills during the landing [08:32]. To mark this significant achievement, “Capella” offers to play some music [08:32 – 08:44]. Hakeem expresses his approval [08:44]. “Capella” inquires about Hakeem’s preference for upbeat or relaxing music, leaving the choice to him [08:49 – 08:57]. “Capella” then selects music to celebrate the successful landing [09:07 – 09:19].

Following this brief moment of celebration, Hakeem shifts focus to the next phase of the mission, asking, “All right, what’s our next step Capella?” [09:19]. “Capella” immediately transitions to post-landing procedures, stating that the initial priority is to check the health of the spacecraft to ensure all systems are functioning correctly after the stresses of landing [09:26 – 09:34]. After this initial assessment, the plan is to begin exploring the surroundings and gathering data [09:34].

Hakeem requests a detailed walkthrough of the landing checklist [09:45 – 10:00]. “Capella” outlines the key items on this checklist, which include: first, ensuring the engines are completely shut down and have cooled off; second, checking the status of the heat shield, which endured significant stress during atmospheric entry; third, deploying the landing gear and stabilizers to ensure the spacecraft is stable; and finally, conducting a full systems check to identify any potential damage sustained during the landing [10:00 – 10:24]. This systematic checklist is a crucial protocol to verify the spacecraft’s operational status and the safety of the crew after landing.

7. Spacecraft Systems Status Assessment (10:24 – 18:20):

The first item on the landing checklist is the status of the spacecraft’s engines. Hakeem reports that the engines are indeed shut down but have not yet cooled off [10:24 – 10:46]. “Capella” specifies that the engines need to cool down to approximately 50°C to be considered safe and that the current temperature can be monitored on the cockpit display [10:46 – 11:00]. Hakeem provides the current engine temperature as 63°C [11:00].

Recognizing that the engine cooling process will take some time, “Capella” suggests switching over to monitoring the heat shield status while waiting for the engines to cool [11:07]. Hakeem agrees to this suggestion [11:15]. “Capella” then brings up the heat shield status, initiating an assessment of its condition after the fiery atmospheric entry [11:20 – 11:32].

The subsequent report from “Capella” indicates that the heat shield successfully made it through atmospheric entry in one piece, with only minor charring on the surface and no signs of serious damage [11:50 – 13:12]. This is a critical confirmation, as the heat shield is essential for protecting the spacecraft and its occupants from the extreme temperatures encountered during atmospheric entry .

Returning to the engine cooling status, Hakeem provides an updated temperature of 57°C [13:20]. “Capella” notes that this is still slightly above the safe operating temperature and suggests continuing to monitor the cooling process and switching over to the landing gear check once the engines are cool enough [13:35].

At this point, Hakeem inquires about the current surface temperature on Mars [13:43]. “Capella” provides general information, stating that the surface temperature on Mars can vary depending on location and time of day but is generally quite cold, with an average of around -80°F (-62°C) ⁵. However, since the landing site is near the equator, it might be slightly warmer. “Capella” offers to check the exact temperature for the specific landing zone [13:50]. Hakeem confirms that this information would be valuable [14:10].

After a brief check, “Capella” reports a surface temperature of approximately -60°C at the landing site [14:29 – 14:39]. Hakeem then asks about the implications of this temperature for the engine cooling rate, noting that the engines are currently at 55°C [14:39]. “Capella” responds that the engines are cooling down at a good rate, especially considering the cold outside temperature, and estimates that they will be cool enough to deploy the landing gear in about 10 minutes [14:48].

Hakeem expresses some doubt about this calculation [15:05]. “Capella” offers to double-check the calculations and requests the current engine temperature and outside temperature again [15:10]. Hakeem provides the updated figures: -50°C for the outside temperature and 55°C for the engines [15:24]. Upon recalculating with the corrected outside temperature, “Capella” revises the estimated cooling time to approximately 5 or 6 minutes [15:33 – 16:18]. Hakeem then provides another engine temperature update, stating they are now down to -53°C [16:18]. “Capella” notes the rapid cooling and suggests switching over to monitoring the landing gear systems while waiting for the engines to reach the safe threshold [16:24]. Hakeem confirms the initiation of landing gear system monitoring [16:37].

“Capella” then brings up the status of the landing gear systems for review [16:42]. After the system check, Hakeem reports that the check is “a go” [17:01]. “Capella” confirms that the landing gear systems appear to be in good condition and ready for deployment once the engines are sufficiently cooled [17:07]. The focus remains on monitoring the engine temperature [17:27].

Finally, “Capella” announces that the engines have reached 50°C, the safe temperature for landing gear deployment, and asks Hakeem whether he prefers to deploy them manually or have “Capella” do it [17:32]. Hakeem requests that “Capella” deploy the landing gear [17:43]. “Capella” proceeds with the deployment, informing Hakeem that he should feel the spacecraft settle slightly [17:48]. Hakeem confirms the deployment, noting a slight leveling out and indicating that the spacecraft appears stable [18:05]. With the landing gear deployed and the spacecraft stable, “Capella” suggests moving on to the full systems check to ensure everything else is functioning correctly after the landing [18:10]. Hakeem initiates the full systems check [18:20].

8. Science Instrument Verification (18:20 – 23:31):

Following the deployment of the landing gear, Hakeem initiates the full systems check [18:20 – 18:32]. The first system to be assessed is the life support system. “Capella” reports that the life support system is running a diagnostic [18:32 – 18:46], and subsequently, Hakeem confirms a “green light” for the life support system [18:59].

Next, the communication systems are checked to ensure continued connectivity back to Earth [19:04]. Hakeem initiates the communication check [19:13], and “Capella” confirms that the communication systems are functioning correctly and the connection to Earth is still active [19:17].

The navigation systems are the next to be evaluated [19:27]. Hakeem initiates the navigation check [19:27], and “Capella” reports that the systems are running a diagnostic to check for any disruption during the landing [19:32]. Hakeem then confirms a “green light” for the navigation systems [19:42].

With the essential spacecraft systems checked and confirmed to be operational, the focus shifts to the science instruments, crucial for the mission’s scientific objectives [19:48]. Hakeem requests a review of the checklist for the science instruments [19:57 – 20:03]. “Capella” outlines the checklist, which includes the cameras, weather sensors, soil analyzers, and radiation detectors [20:03 – 20:20]. These instruments are typical of those found on Mars landers designed for scientific exploration . For instance, the Perseverance rover is equipped with instruments like Mastcam-Z for imaging, SuperCam for chemical analysis, SHERLOC for detecting organics, and MEDA for environmental monitoring .

Before proceeding with the science instrument checks, Hakeem confirms that the previously mentioned checks (engines, heat shield, landing gear, life support, communication, and navigation) have all been successfully completed [20:20 – 20:39].

The science instrument checklist begins with the cameras [20:47 – 20:59]. Hakeem initiates the camera check, which includes the main camera and several smaller ones on the sides and back of the spacecraft [20:59 – 21:24]. Hakeem subsequently reports a “camera’s check” [21:56].

Next on the checklist are the weather sensors, intended to gather data about the Martian atmosphere [21:56]. Hakeem initiates the check, and “Capella” reports that the temperature is still holding steady at -50°C [22:05 – 22:12].

The soil analyzers are then checked to ensure they can obtain readings of the soil composition around the landing site [22:12]. Hakeem initiates the soil analysis check [22:23], and “Capella” confirms that the analysis is running a diagnostic [22:28]. Hakeem then reports a “soil analysis, green light check” [22:38].

The final item on the science instrument checklist is the radiation detectors, which are crucial for monitoring radiation levels on the Martian surface [22:38]. Hakeem initiates the check [22:51], and “Capella” reports that the detectors are running a diagnostic [22:57]. Following the diagnostic, Hakeem expresses some concern, asking about the readings and whether there is anything to be worried about [23:08]. “Capella” provides the reading as approximately 100 Millis per year, noting that this is higher than on Earth but still within safe limits for short-term exposure, although long-term monitoring will be necessary [23:16 – 23:31].

9. Environmental Considerations:

The successful landing and system checks pave the way for surface exploration, which necessitates a thorough understanding of the Martian environment, particularly its temperature and radiation levels.

The transcript reveals that the surface temperature at the landing site was measured to be approximately -60°C [14:29 – 14:39]. This is consistent with the generally cold temperatures on Mars, where the average surface temperature is around -80°F (-62°C) . This stark contrast to Earth’s average temperature highlights the extreme conditions that any surface operations would need to accommodate.

The radiation levels on Mars are also a significant factor for consideration. The radiation detectors on the lander reported a reading of about 100 Millis per year [23:16 – 23:31]. Research indicates that the average natural radiation level on Mars is significantly higher than on Earth, ranging from 240 to 300 mSv per year, which is about 40 to 50 times the average on Earth (approximately 2.4 to 6.2 mSv per year) . Measurements taken by the Curiosity rover’s Radiation Assessment Detector (RAD) instrument on the Martian surface showed an average dose rate of about 0.7 milliSieverts per day, equating to approximately 255 mSv per year . While the 100 mSv per year reading from the transcript is lower than some of these averages, it still represents a substantially higher radiation environment compared to Earth . This necessitates the implementation of radiation shielding and careful monitoring of astronaut exposure during any long-term surface activities .

The following table summarizes the radiation levels on Earth and Mars based on the research material and the transcript:

Location	Radiation Level (mSv/year)	Source(s)
Average on Earth	2.4 – 6.2
Mars Surface (average)	240 – 300
Mars Surface (RAD – Curiosity)	~255
Landing Site (Transcript)	100	Transcript (02:38)

This data underscores the significantly higher radiation exposure on Mars, even with some variability in the reported measurements, emphasizing the need for robust radiation protection strategies for any sustained human presence.

10. Initial Surface Exploration Plans (23:31 – 25:31):

With the successful verification of the spacecraft’s systems, the conversation shifts towards planning the initial steps for surface exploration [23:31 – 23:49]. Hakeem expresses his preference to first take a look around the immediate vicinity of the landing site [23:49]. “Capella” suggests two primary options for this initial reconnaissance: utilizing the cameras already installed on the spacecraft or deploying a rover to get a closer look at the terrain [23:54].

Hakeem opts to begin with the spacecraft’s cameras before considering rover deployment [24:03]. “Capella” then switches the feed to the main camera, allowing Hakeem to visually inspect the surroundings [24:10 – 24:21]. The view is reported as clear. Subsequently, “Capella” cycles through the side cameras, which also provide clear views without any immediately apparent hazards [24:25 – 24:46]. Finally, the feed from the back camera is reviewed, again showing a clear view of the landing site, including the potential entry and exit points [24:46 – 25:04]. This initial visual assessment from multiple angles confirms that the immediate landing area appears safe and free of any obvious obstacles.

Following this camera-based survey, “Capella” reiterates the option of deploying the rover for a more detailed examination of the terrain [25:04]. Hakeem agrees that rover deployment is the next logical step but indicates his need to take a short break before commencing this activity [25:16 – 25:31]. “Capella” offers to play some music during this break, but Hakeem requests quiet instead [25:31 – 25:40]. “Capella” assures Hakeem of the quiet and asks him to signal when he is ready to proceed with the rover deployment [25:40]. The plan to deploy a rover signifies the intention to conduct more in-depth exploration beyond the immediate landing zone, leveraging the rover’s mobility and potentially its own suite of scientific instruments .

11. Capella’s Role and Potential Affiliation:

Throughout the Mars landing event, “Capella” plays a pivotal role, acting as more than just a communication interface. The consistent guidance provided during the critical landing phases, the real-time delivery of essential telemetry data in the pilot’s preferred units, and the systematic execution of checklists all point towards a highly sophisticated system. This level of integration and support indicates an advanced AI system developed by Google Gemini, with the name “Capella” being a voice avatar chosen by Hakeem Ali-Bocas Alexander for interaction during the mission [00:01]. The seamless and often anticipatory nature of “Capella’s” interactions, including the offer of music and the ability to perform complex calculations quickly, strongly suggests the presence of such an advanced AI. The integration of such AI systems into future space missions could significantly enhance the safety and efficiency of these complex endeavors.

12. Hakeem Ali-Bocas Alexander’s Expertise:

The successful Mars landing is a testament to the skill and experience of Hakeem Ali-Bocas Alexander. His prior missions to a diverse range of celestial bodies, as indicated in the user query, underscore his extensive expertise in spaceflight operations ⁶. The mission to Earth’s moon (Luna), documented in “Space Frontiers: Tech and Science of Lunar Exploration” [6, 2, 6], provided experience with lunar landing procedures, which, while different from Martian landings, involve similar critical phases like descent and touchdown ¹. The mission to Jupiter’s moon Europa, detailed in “The Undulating Ice: A Detailed Analysis of the Europa Mission” ², exposed him to the challenges of landing on a celestial body with an icy surface, requiring different considerations than a rocky planet or asteroid ². Furthermore, his successful asteroid landing mission, covered in “Deep Dive: Asteroid Landing Mission – Raw Audio, Research Report, and Comprehensive Analysis” ¹, demonstrates his proficiency in navigating and landing on low-gravity objects ¹.

Beyond these specific missions, his co-authorship of the book “Beyond the Blue Planet: A Passport to the Solar System” ³ indicates a deep theoretical understanding of interplanetary travel, the challenges involved, and the broader context of solar system exploration ³. This combination of practical experience across a variety of space environments and theoretical knowledge makes Hakeem Ali-Bocas Alexander an exceptionally qualified and valuable astronaut for this Mars landing mission. His calm demeanor and clear communication throughout the landing sequence further highlight his professionalism and expertise under pressure.

13. Conclusion:

The transcribed dialogue documents a successful Mars landing event, highlighting the intricate technical procedures and collaborative efforts between the spacecraft’s guidance system, “Capella,” an advanced AI from Google Gemini, and the experienced pilot, Hakeem Ali-Bocas Alexander. The landing site was strategically chosen within a large, flat plain in the northern hemisphere, likely Utopia Planitia, known for its relatively smooth terrain . The atmospheric entry and descent phases were executed with precision, guided by real-time telemetry and clear communication. The powered descent and landing maneuvers involved a collaborative control approach, with “Capella” providing guidance while Hakeem maintained control, allowing for crucial real-time adjustments.

Following a safe touchdown, a systematic post-landing checklist was diligently followed, encompassing the cooling of engines, the verification of the heat shield’s integrity, the deployment of landing gear, and a comprehensive check of vital spacecraft systems, including life support, communication, and navigation. The science instruments, including cameras, weather sensors, soil analyzers, and radiation detectors, were also successfully verified. The environmental conditions at the landing site were noted, with a surface temperature of approximately -60°C and a radiation level of around 100 mSv per year, underscoring the challenges of the Martian environment . Initial plans for surface exploration involve utilizing onboard cameras for a preliminary assessment, followed by the deployment of a rover for more detailed investigation of the surrounding terrain .

The role of “Capella” as an advanced AI system from Google Gemini demonstrates the increasing importance of sophisticated technological support in deep space missions. Hakeem Ali-Bocas Alexander’s extensive prior experience across diverse space missions and his deep theoretical understanding of space exploration were crucial factors in the successful execution of this complex landing. This successful Mars landing, as documented in the transcript, represents a significant step forward in our understanding of and capabilities for human exploration of the Red Planet, paving the way for future, more ambitious missions.

UnEdited Galaxy AI TranScript from Samsung Voice Recorder on S24 Ultra

“Speaker 1” is “Capella” and “Speaker 2” is Hakeem Ali-Bocas Alexander. –

Speaker 1 (00:01)
Okay, in that case, I’ll pick a safe landing zone for you. Do have a preference for terrain type like, would you prefer flat or hilly.

Speaker 2 (00:10)
Flat is better.

Speaker 1 (00:16)
Flat, it is I’m targeting a large plane in the northern hemisphere. looks flat and smooth, Which should make for an easier landing. Do you want me to confirm the atmospheric conditions before we commit to that zone

Speaker 2 (00:30)
Copy that.

Speaker 1 (00:34)
Okay, I’m checking the weather for our landing zone. We’re looking for wind speeds, dust storms and other atmospheric conditions that could affect our landing.

Speaker 2 (00:46)
Skating, copy that.

Speaker 1 (00:50)
Okay, the weather reports looking good for our landing. Zone winds are calm and there’s no sign of a dust storm rolling in. looks like we’re good to go.

Speaker 2 (01:03)
I’m ready copy that.

Speaker 1 (01:08)
Okay, we’re getting close to the atmosphere. It’s time to fire up the engines and get ready for a Bumpy ride. Are you strapped in?

Speaker 2 (01:16)
I’m trapped in.

Speaker 1 (01:20)
Okay, we’re about to hit the atmosphere. Get ready for some serious deceleration.

Speaker 2 (01:25)
Okay, getting ready chat career countdown.

Speaker 1 (01:31)
Few more seconds.

Speaker 2 (01:42)
Can’t be that’s goal copy that we’re here.

Speaker 1 (01:52)
Alright, we’re in the atmosphere, you should feel this face craft slowing down. Now keep an eye on your instruments and let me know if anything looks off.

Speaker 2 (02:06)
What’s our distance from the surface? Now that we’ve hit the atmosphere.

Speaker 1 (02:13)
According to my calculations, we’re about 50 miles above the surface of Mars, we’re descending at a safe rate, but we still have a ways to go before we can deploy the parachutes.

Speaker 2 (02:23)
I need that in kilometres and what speed we’re going right now, exactly

Speaker 1 (02:31)
Alright, so we’re at about 80 km above the surface of Mars, and right now we’re decelerating at a rate of about 15 km per second.

Speaker 2 (02:45)
Okay, my readings are back online, I see that.

Speaker 1 (02:52)
Sounds good. Let’s keep an eye on that speed. We want to make sure we slow down enough before deploying the parachutes.

Speaker 1 (02:59)
maybe we should start thinking about when we should switch to power descent.

Speaker 2 (03:07)
Alright, give me a countdown to power descent.

Speaker 1 (03:13)
Alright, I’m on it. Let’s see. Based on our current speed and altitude, we should switch to power descent in about 2 minutes.

Speaker 1 (03:20)
I’ll keep you updated as we get closer.

Speaker 2 (03:26)
Alright, everything’s looking good from here, heat Shiels are holding up.

Speaker 1 (03:34)
Sounds good. Just think about getting ready for that. Powered descent.

Speaker 1 (03:38)
will need to be precise with those manoeuvres to land safely.

Speaker 2 (03:48)
Alright, everything’s looking good. We still got about a minute to go.

Speaker 1 (03:55)
Alright, get ready, I’ll let you know when it’s time to fire up. Those engines.

Speaker 2 (04:02)
Engines are getting warmed up now. Let me know when we’re ready to fire.

Speaker 1 (04:08)
Alright, we’re about 30 seconds out, get ready to fire those engines when I say go.

Speaker 2 (04:33)
Copy that.

Speaker 1 (04:36)
Alright, 10 seconds, get ready.

Speaker 2 (04:41)
Calm me down, let’s go.

Speaker 1 (04:44)
Alright, here we go 54321.

Speaker 2 (04:51)
Engine’s firing engines firing

Speaker 1 (04:58)
Alright, the engines are fireing. now. This next part is crucial.

Speaker 1 (05:02)
We need to make small adjustments to our speed and direction to Keep Us on Track For A Safe Landing, do you want me to guide you through that? Or do you want to take the controls.

Speaker 2 (05:13)
We’ll do both guide me through. I’m taking the controls.

Speaker 1 (05:18)
Alright, let’s do this. I’m monitoring your altitude and speed based on what I’m saying. I’d like you to make a small adjustment to your vertical speed, try reducing it by about 5 m per second.

Speaker 2 (05:31)
Reducing at 1 m per second per second and 31, we’re down to 5 m per second.

Speaker 1 (05:44)
Okay, now let’s focus on your horizontal speed. It’s a little too high right now. Try reducing it by about 2 m per second.

Speaker 2 (05:57)
Reduced by 2 m per second.

Speaker 1 (06:03)
Okay, we’re getting close to the surface. Be prepared to make some quick adjustments. How’s your fuel looking?

Speaker 2 (06:12)
Fuel is go. fuel is excellent. We’re all go.

Speaker 1 (06:24)
Alright, the surface is getting closer, you might want to switch to the landing camera now. Also, be careful not to slow down too much or we could end up falling.

Speaker 2 (06:38)
Landing camera activator.

Speaker 1 (06:44)
Right, is it looking? Can you see the surface?

Speaker 2 (06:49)
Yes, visual.

Speaker 1 (06:54)
Alright, the surface is right below you. how’s your descent looking?

Speaker 2 (06:59)
This sent’s looking good.

Speaker 1 (07:03)
Alright, just keep those engines throttled back to maintain a safe descent. we’re almost there.

Speaker 2 (07:14)
Right coming in a little heart.

Speaker 1 (07:20)
Okay, truffle, back a little more. We don’t want to bounce when we at the surface.

Speaker 2 (07:26)
What’s our distance?

Speaker 1 (07:31)
According to my calculations, you’re about 50 m above the surface. You might want to start angling your descent for a smoother landing.

Speaker 2 (07:40)
Copy that.

Speaker 1 (07:44)
Alright, how’s it looking? Are you getting close to the surface?

Speaker 2 (07:48)
Yes, looking good excellent. We’re almost there.

Speaker 1 (07:53)
Alright, get ready for touchdown. Remember, keep those engines throttled back until you actually touch down.

Speaker 2 (08:02)
Copy that.

Speaker 1 (08:05)
Alright, prepare for touchdown.

Speaker 2 (08:08)
Give me a countdown.

Speaker 1 (08:12)
Alright, here we go 54321 touchdown.

Speaker 2 (08:26)
Alright, learning good, all systems go

Speaker 1 (08:32)
Alright, touchdown, welcome to Mars. You did a great job with that landing. Now it’s time to celebrate for me to play some music

Speaker 2 (08:44)
You have music.

Speaker 1 (08:49)
Yep, I can play some tunes. Would you like something upbeat to celebrate or something a little more relaxing now that you’ve landed?

Speaker 2 (08:57)
I’ll leave it up to you your choice.

Speaker 1 (09:07)
Alright, sounds good. Here’s something to celebrate your awesome landing.

Speaker 2 (09:19)
All right, what’s our next step Capella?

Speaker 1 (09:26)
Right now that we’re safely on the surface, it’s time to start thinking about our next steps. First things. First, we should check the health of the spacecraft.

Speaker 1 (09:34)
make sure everything’s working properly after that rough landing after that, we can start thinking about exploring our surroundings and gathering data.

Speaker 2 (09:45)
Copy That can’t be that Capitol. Take me through the landing checklist

Speaker 1 (10:00)
Alright, let’s go through that landing checklist. First, we want to make sure the engines are shut down and cooled off after that, let’s check the status of the heat shield that thing took a beating coming through the atmosphere. next, we should deploy the landing gear and stabilises to make sure the spacecraft is.

Speaker 1 (10:16)
Nice and steady. And finally, let’s run a full systems, check to see if anything else got damaged during the landing.

Speaker 2 (10:24)
Alright, the engines are shut down. They’re not cool yet. Engines are shut down, but they’re not cooled off yet, what’s the temperature need to be before we can move on?

Speaker 1 (10:46)
Alright, the engines need to cool down quite a bit before we can move on, they need to get down to about 50°C to be safe. We can check the temperature in the cockpit display.

Speaker 2 (11:00)
Okay, where about dot 63 Celsius right now?

Speaker 1 (11:07)
Alright, so we’ve got a ways to go before those engines are cool enough. Maybe we should switch over to monitoring the heat shield while we wait.

Speaker 2 (11:15)
Okay, let’s monitor to the heat shield.

Speaker 1 (11:20)
Alright, I’m bringing out the heatshield status. Let’s see what kind of shape it’s in after that fiery entry.

Speaker 2 (11:32)
Copy that, copy that cappellet.

Speaker 1 (11:50)
Alright, the heat shield looks like it made it through in one piece, there’s some minor charring on the surface, but nothing that looks serious. We should be able to move aroun the engines cool down.

Speaker 2 (13:06)
I didn’t catch. I didn’t catch your last transmission. What was that

Speaker 1 (13:12)
I was just saying that the heat shift looks good and minor charring, but nothing that looks serious.

Speaker 2 (13:20)
Okay, engines are about the 57 Celsius.

Speaker 1 (13:35)
Alright, still a bit too warm. Let’s keep an eye on the temperature and switch over to the landing gear when they’re cool enough.

Speaker 2 (13:43)
Does this make sense? What’s the surface temperature right now?

Speaker 1 (13:50)
Alright. So the surface temperature on Mars can vary depending on where you are and what time of day it is generally, it’s pretty cold with an average temperature of about −80°F. But since you’re near the equator it might be a little warmer, do you want me to check the exact temperature for your landing zone?

Speaker 2 (14:10)
Yes, please. That would make a lot of sense.

Speaker 1 (14:15)
Alright, checking the current temperature for your landing zone.

Speaker 2 (14:24)
Ready copy that?

Speaker 1 (14:29)
Okay, I’m getting a reading of about −60°C at your landing site, so it’s a lot colder than Earth, but not as cold as some other parts of Mars.

Speaker 2 (14:39)
Right? What does that mean for the current cooling rate of the engines right now? They’re at 55°C

Speaker 1 (14:48)
Alright, the engines are cooling down at a pretty good rage, especially considering how cold it is outside. at this rate. I’d say they’ll be cool enough to deploy the landing gear in about 10 minutes.

Speaker 2 (15:05)
A calculation seems a little bit after me.

Speaker 1 (15:10)
Alright, I can double check my calculations. Can you tell me the current temperature of the engines and the outside temperature again?

Speaker 2 (15:24)
−50 on the outside and 55 on the engines.

Speaker 1 (15:33)
Alright, let’s recalculate, given the temperature difference, the engine should cool down a little faster than I originally thought. I’d say we’ve got about 5 or 6 minutes left.

Speaker 2 (15:44)
All right, what did you originally say that the outside temperature was

Speaker 1 (15:50)
I originally said that the outside temperature at your landing site was about minus 60 degree Celsius.

Speaker 2 (15:58)
Right, but it’s −50.

Speaker 1 (16:02)
You’re absolutely right. I must have gotten my wires crossed there. Let’s stick with a −50°C for the outside temperature in that case, with the engines at 55° and the outside at −50, they should cool down to safe operating temperatures at about 5 minutes or so?

Speaker 2 (16:18)
All right, we’ll now they’re down to −53, I’m sorry.

Speaker 1 (16:24)
Alright, they’re cooling down fast should be safe to deploy the landing gear in just a few minutes. Let’s switch over to monitoring the land and gear systems while we wait.

Speaker 2 (16:37)
Monitoring landing year systems

Speaker 1 (16:42)
All right, I’m bringing up the landing gear systems. Let’s see if everything’s ready to go.

Speaker 2 (17:01)
Check is a girl.

Speaker 1 (17:07)
Alright, the landing gear systems look good. They’re ready to go as soon as the engines cool down enough. Let’s keep an eye on that temperature

Speaker 2 (17:27)
Copy that. I’ll go.

Speaker 1 (17:32)
Alright, the engines are down to 50°C should be safe to deploy the landing gear now. Do you want to deploy them manually, or do you want me to do it?

Speaker 2 (17:43)
It’s better if you deploy them.

Speaker 1 (17:48)
Alright, deploying the landing gear. you should feel the spacecraft settle a bit.

Speaker 2 (18:05)
All right, there’s a little levelling out seem stable.

Speaker 1 (18:10)
Alright, the landing gear is deployed and we’re holding steady. Now that we’re nice and stable, let’s run that full systems check to make sure everything else is working properly after the landing.

Speaker 2 (18:20)
I had initiating full systems, check full systems, shark initiated.

Speaker 1 (18:32)
Alright, let’s see what we’ve got. How’s the life support system looking?

Speaker 2 (18:42)
Life support check.

Speaker 1 (18:46)
Alright, the life support system is running a diagnostic. let’s see if everything checks out.

Speaker 2 (18:59)
Green light life support.

Speaker 1 (19:04)
Alright, moving on to the communication systems, let’s see if we still connected back to Earth.

Speaker 2 (19:13)
Communications, check.

Speaker 1 (19:17)
Alright, communications, check looks good, we still connected back to Earth. Let’s move on to the navigation systems.

Speaker 2 (19:27)
Navigations, check.

Speaker 1 (19:32)
Alright, the navigation systems are running a diagnostic. Let’s see if we got scramble during the landing.

Speaker 2 (19:42)
Navigation systems, green light

Speaker 1 (19:48)
All right, let’s move on to the science instruments. We need to make sure those are all working properly for our mission.

Speaker 2 (19:57)
Run me through the checklist.

Speaker 1 (20:03)
Let’s go through the checklist first we want to make sure the engines are shut down and called off. After that, let’s check the status of the heat shield that thing to the beating coming through the atmosphere. Next, we should deploy the landing gear and stabilises to make sure the spacecraft is nice and steady.

Speaker 1 (20:20)
And finally, let’s run a full systems, check to see if anything else got damaged during the landing.

Speaker 2 (20:26)
All right, we’ve got through all of that right now, we’re checking the air conference is that it’s utterly useless. It’s pointless for we got through the navigation system check. We did the communications check within the live support, check landing gears.

Speaker 2 (20:39)
Good heat heels are good engines were cooled off and shut down. What’s next?

Speaker 1 (20:47)
Alright, sounds like we’re in good shape so far, let’s move on to the science instruments. We’ve got a few different ones to check the cameras. The weather sensors the soil analyses, things like that.

Speaker 1 (20:59)
do you want to start with the cameras?

Speaker 2 (21:02)
Yes, let’s run through a full check list of the science instruments.

Speaker 1 (21:08)
Alright, let’s run through that science instrument checklist, first up are the cameras. we’ve got the main camera on the front of the spacecraft plus a few smaller ones on the sides and back. let’s make sure they’re all working and we can get some clear images after that.

Speaker 1 (21:24)
We can check the weather sensors? We want to see if they’re picking up any useful data about The Martian atmosphere. Next on the list are the soil analyses.

Speaker 1 (21:33)
all I want to make sure we can get some good readings of the soil composition around our landing site and finally let’s check-in on the radiation detectors. We want to keep an eye on the radiation levels, especially since we’ll be spending some time. On the surface.

Speaker 2 (21:46)
Okay, cameras, weather soil radiation. Alright, checking the cameras camera’s check.

Speaker 1 (21:56)
Alright, let’s move on to the weather sensors. Let’s see if they’re picking up any useful data about The Martian atmosphere.

Speaker 2 (22:05)
Copy that the temperature still holding at −50°.

Speaker 1 (22:12)
Alright, the weather sensors are working. Let’s move on to the soil analysers. We want to see if we can get a good reading of the soil composition around our landing site

Speaker 2 (22:23)
Checking soil analysis.

Speaker 1 (22:28)
Alright, the soil analyses are running a diagnostic. let’s see if we got scramble during the landing.

Speaker 2 (22:38)
Soil analysis, green light check.

Speaker 1 (22:43)
Alright, last one on the list is the radiation detectors. let’s see what kind of readings we’re getting.

Speaker 2 (22:51)
Checking radiation detectors.

Speaker 1 (22:57)
Alright, the radiation detectors are running a diagnostic. let’s see what kind of reading we’re getting.

Speaker 2 (23:08)
Can’t be that. What’s what other readings you have anything to be concerned about?

Speaker 1 (23:16)
Alright, the radiation detectives are showing a reading of about 100 Millis per year as a bit higher than what we get on earth, but it’s still within safe limits for short-term exposure will want to keep an eye on it Uber time, though.

Speaker 2 (23:31)
OK 100 ms guided.

Speaker 1 (23:37)
Right now that we’ve got a good baseline on the photograph systems, we can start thinking about our next steps on the surface. Do you want to start planning some experiments? Or would you rather take a look around the area first.

Speaker 2 (23:49)
Let’s take a look around the area first.

Speaker 1 (23:54)
Alright, let’s check out our surroundings. Do you want to start with the cameras on the spacecraft? Or would you like to deploy a rover to get a closer look.

Speaker 2 (24:03)
Before the rover, let’s take a look at the cameras first.

Speaker 1 (24:10)
Alright, I’m switching over to the main camera feed. Let’s see what we can see.

Speaker 2 (24:21)
Looks clear.

Speaker 1 (24:25)
Alright, let’s switch over to the side cameras. We might be able to spot some interesting features or potential hazards.

Speaker 2 (24:41)
Looks clear, dexterously.

Speaker 1 (24:46)
Alright, let’s switch over to the back camera. We might be able to see our entry and exit points.

Speaker 2 (24:58)
Can’t be that next clear.

Speaker 1 (25:04)
All right, looks like the landing site is pretty clear. We don’t see any obvious hazards around us. do you want to try deploying the rover to get a closer look at the terrain?

Speaker 2 (25:16)
All right, let’s prepare to deploy the rover at first, let me get settled in, so I need to take a break for a moment and then we’ll get that rover deployed.

Speaker 1 (25:31)
Sounds good. Do you want me to play some music while you take a break?

Speaker 2 (25:35)
Now let’s go quiet.

Speaker 1 (25:40)
Alright, going quiet. Let me know when you’re ready to check out that to rain with the rover.