Open Technical Archive · Distribution Unrestricted Controlled terminology applies · TCT ruling MBI-TCT-09
Meridian Boundary Institute Planar Cosmological Systems · Technical Archive
Archive series MBI-TR / MBI-TN / MBI-FP
Current model statement MBI-TR-01 Rev. A (Preliminary)
Terminology authority Technical Communications & Terminology Office
Preliminary Model Statement · Open Technical Dossier

Apparent Sphericality in Binary Planar Cosmology

The Binary Flat Earth Model proposes a binary planar cosmological system governed by magnetogravitic field equilibrium. The observable Primary Plane is opposed by an inferred Counterplane across a field-interaction zone; within the model, the paired firmamental boundaries would generate the Apparent Spherical Envelope.

Sphericality is treated here as an appearance condition, not a settled structural claim. MBI-TR-01 §1.1, preliminary model position

Model architecture and controlled nomenclature

Section 1 · MBI-TR-01 §2

The Binary Flat Earth Model reclassifies the observed globe as an envelope condition. Four structures and two field conditions define the system. Terms below are controlled nomenclature under TCT ruling MBI-TCT-09 and must not be substituted in derivative material.

Table 1 — System components and field conditions (per MBI-TR-01 §2.1–2.6)
Ref. Term Class Definition
§2.1Primary PlaneCore componentThe observable terrestrial plane on which direct measurement, biological activity, and local downward acceleration occur. The only directly observed terrestrial plane in the model.
§2.2CounterplaneInferred componentThe opposing inferred terrestrial plane required by binary planar equilibrium. Its status is inferential rather than exploratory; it is not directly observed.
§2.3Paired FirmamentsBoundary structureTransparent dome-like boundary structures enclosing each plane. Their combined external silhouette generates the Apparent Spherical Envelope.
§2.4Apparent Spherical EnvelopeObservationThe sphere-like outer silhouette generated by the paired firmamental boundaries; commonly misinterpreted as evidence of a continuous spherical terrestrial mass.
§2.5Equilibrium VoidField regionThe field-interaction zone between the two planes. Not empty space: the region where planar gravitation, opposed firmamental polarity, field compression, and occlusion behaviour converge.
§2.6Bilateral Occlusion FieldField conditionThe occluding condition (Magnetogravitic Occlusion Layer) preventing direct observation, signal coherence, and physical traversal between the planes.
APPARENT SPHERICAL ENVELOPE PRIMARY PLANE CONCEALED COUNTERPLANE INFERRED MBI-TR-01 / FIG. 2 / OBSERVED ENVELOPE CONDITION REV A / PSM
Observed condition: the external spherical silhouette, internal planes shown in dashed section. FIG. 2
PAIRED FIRMAMENTS PRIMARY PLANE COUNTERPLANE INFERRED EQUILIBRIUM VOID / OCCLUSION FIELD MUTUAL PLANAR GRAVITATION vs OPPOSED DOME POLARITY NO AXLE, PILLAR, TETHER, OR MECHANICAL CONNECTOR MBI-TR-01 / FIG. 3 / REVEALED BINARY PLANAR ARCHITECTURE REV A / PSM
Sectional view: force balance across the Equilibrium Void. Under this hypothesis, the planes remain separated by field interaction rather than a visible structural support. FIG. 3

Interactive model viewer

MBI-VM-01 · Canonical route

The interactive model is hosted here as a Meridian Boundary Institute research artefact. Other public surfaces use lightweight preview cards and link back to this canonical page rather than loading the full model on their homepages.

Viewer architecture

The Binary Flat Earth Model

A poster-first route for the shared 3D visualisation: static preview on first load, interactive layer only after the visitor enters the model.

  • Canonical source: Meridian Boundary Institute
  • Public links: Counterplane Awakening, Janus Earth, Second Sky, BinaryPlanar
  • Production slot: Three.js/WebGL model layer
Preview render of the Binary Flat Earth Model showing paired planes and the Bilateral Occlusion Field
MBI-VM-01 previewposter-first model route

Technical Report MBI-TR-01

Section 2 · Current model statement

Apparent Sphericality in Binary Planar Cosmology

MBI-TR-01 · Rev. A

Magnetogravitic Field Equilibrium and Boundary Occlusion in the Binary Flat Earth Model

Abstract (excerpt)

The Binary Flat Earth Model proposes a binary planar cosmological system in which the observable terrestrial surface, designated the Primary Plane, is opposed by an inferred Counterplane across a magnetogravitic field-interaction zone. When considered as a coupled system, the paired firmaments would generate an Apparent Spherical Envelope: a sphere-like observational silhouette interpreted here as distinct from a continuous spherical terrestrial mass.

MBI-TN-06 series notes further model the Equilibrium Void as an anisotropic interfacial zone containing Janus-type particulate behaviour: boundary particles with opposed surface properties, one face coupled to the Primary Plane and one face coupled to the Counterplane. The term is borrowed from established colloid science, where Janus particles designate particles with two chemically or physically distinct faces.

The model does not reject sphericality as an observed condition. It reclassifies sphericality as an envelope phenomenon rather than a structural property within this hypothesis. The unresolved question is not the observation of sphericality, but whether the spherical envelope corresponds to a spherical terrestrial body.

Sections 13 Figures 10 Companion notes 6 Status Preliminary Distribution Open dossier

Meridian Boundary Institute. Apparent Sphericality in Binary Planar Cosmology: Magnetogravitic Field Equilibrium and Boundary Occlusion in the Binary Flat Earth Model. Technical Report MBI-TR-01, Department of Planar Systems Modelling. No DOI or external institutional affiliation is assigned in this draft.

Stability conditions (§4)

  1. Mutual Planar Gravitation draws the Primary Plane and Counterplane toward one another across the Equilibrium Void.
  2. Opposed Dome Polarity prevents collapse by producing a separating firmamental field.
  3. Their interaction produces Bilateral Magnetostatic Equilibrium, stabilising the system without axle, pillar, tether, hinge, bearing, gear, bridge, column, or mechanical spacer.

Occlusion and non-contact (§5)

  • The Bilateral Occlusion Field prevents physical traversal, direct observation, and signal coherence between the planes.
  • Signal coherence failure: transmissible signal continuity is lost across the Equilibrium Void.
  • The Counterplane therefore remains an inferred requirement of binary planar equilibrium, not a directly observed terrestrial surface.

Figure plate sheet MBI-FP-01

Section 3 · Field Imaging & Residual Curvature Laboratory

Plate set MBI-FP-01 carries two finished figures: one establishing the revealed system architecture, the other defining the first observational field category. Remaining plates from the MBI-TR-01 figure list are in preparation.

Table 2 — Plate sheet MBI-FP-01, current holdings
Plate Title Content summary Status Record
FIG. 03 Revealed binary planar architecture Cutaway of the Primary Plane, Counterplane, Paired Firmaments, and Equilibrium Void, drawn with no axle, pillar, tether, or mechanical connector. Issued View plate
FIG. 10 Apparent Curvature Residual Long-baseline horizon imaging under envelope interpretation. The residual is framed as envelope-consistent, not as proof of the Counterplane. Issued View plate
FIG. 01–09 Remaining TR-01 figure list Conceptual loop, envelope views, sectional cutaways, gravitation vectors, polarity field lines, force-balance schematic, occlusion field, firmament rotation. In preparation Plate sheet
MBI-FP-01 / SLOT AFormal diagram plate for the plate sheet lead position.
MBI-FP-01 / SLOT BReference still from the physical/3D prototype series.
MBI-FP-01 / SLOT CSurvey field-note scan, Bilateral Horizon Survey Unit.

Technical note series

Section 4 · Archive series MBI-TN

Narrow memoranda from the institute's continuing technical archive. Each note develops one constraint or observational category of the Binary Flat Earth Model established in MBI-TR-01.

Table 3 — Technical note index, series MBI-TN
Note No. Title Subject Status Record
MBI-TN-04.17 On the Apparent Curvature Residual in Bilateral Horizon Imaging First observational hook for the model's predicted horizon behaviour. Available Open note
MBI-TN-05.02 Mutual Planar Gravitation and the Stability Conditions of Opposed Dome Polarity Stability conditions under paired firmamental polarity. Available Open note
MBI-TN-05.09 The Counterplane Requirement in Binary Planar Equilibrium Models Inference without observation or public speculation. Available Open note
MBI-TN-06.11 Magnetogravitic Occlusion and Signal Coherence Failure Across the Equilibrium Void Why signal cannot remain coherent across the occlusion layer. Available Open note
MBI-TN-06.18 Janus Particulate Behaviour at the Bilateral Interface Proposed two-faced boundary particles in the Equilibrium Void; Primary-facing and Counterplane-facing surface states. In preparation Abstract pending
MBI-TN-07.03 Contralateral Firmament Rotation Under Paired Boundary Conditions Field shear without mechanical linkage. Available Open note
MBI-TN-08.22 Reassessing Spherical Continuity Under Paired Firmamental Boundary Conditions Globe interpretation reviewed under firmamental conditions. Available Open note

Departments, programmes, and principal staff

Section 5 · Institute structure
Table 4 — Organisational units of the Meridian Boundary Institute
Code Unit Remit
PSMDepartment of Planar Systems ModellingOwns the formal architecture of the Binary Flat Earth Model, its components, and constraints.
MBDMagnetogravitic Boundary Dynamics ProgrammeStudies field equilibrium, interplanar occlusion, firmamental polarity, and stability conditions.
BHSBilateral Horizon Survey UnitConducts field observation, horizon imaging, and apparent curvature residual documentation.
OASOffice of Apparent Sphericality ResearchStudies the distinction between observed sphericality and structural sphericality.
CAHCosmographic Archive and Historical Systems UnitMaintains archival and historical context for cosmographic and boundary theories.
FIRField Imaging and Residual Curvature LaboratoryProcesses survey imagery and produces residual plots and figure plates.
TCTTechnical Communications and Terminology OfficeProtects controlled terminology across reports, diagrams, and public statements.
Identification photograph of Dr Elias Voss Dr Elias Voss
Director of Planar Systems Modelling
PSM
Identification photograph of Dr Helena Quist Dr Helena Quist
Director of Magnetogravitic Boundary Dynamics
MBD
Identification photograph of Mara Ellison Mara Ellison
Senior Field Observer, Bilateral Horizon Survey Unit
BHS
Identification photograph of Dr Bernard Sloane Dr Bernard Sloane
Emeritus Fellow, Historical Cosmographic Systems
CAH
CAH / PHOTO 01Survey instrument documentation, Bilateral Horizon Survey Unit.
CAH / PHOTO 02Cosmographic Archive working surface.
CAH / DOC 03Accessioned memorandum, institute records.

Terminology boundary

Section 6 · TCT ruling MBI-TCT-09

Popular communities have adopted the term Janus Earth to describe the model's paired geometry. The Meridian Boundary Institute does not use mythological nomenclature in technical material.

The formal term is the Binary Flat Earth Model: a binary planar cosmological model governed by magnetogravitic field equilibrium. Janus Earth is acknowledged only as public terminology, typically when correcting external usage.

Terms excluded from formal material (MBI-TR-01 §9.4)
  • Janus Earth as primary term
  • twin Earth
  • mirror world
  • parallel Earth
  • other side civilisation
  • two-faced Earth
  • awakening language
  • prophecy language
  • hidden world language
Formal stance

Janus Earth is public terminology. Binary Flat Earth Model is the formal technical term.

Correspondence · Technical Desk

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