TESTING GUIDE

Continuity Testing Guide: Ring Final Circuit & CPC Testing

The complete UK electrician's guide to continuity testing — ring final circuit end-to-end and cross-connected tests, r1+rn, r2, and r1+r2 values, CPC continuity, bonding conductor testing, and recording results on the schedule of test results.

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13 min readUpdated 2026-07-02Andrew Moore, Founder of Elec-Mate

Written and reviewed by Andrew Moore, founder of Elec-Mate, against BS 7671:2018+A4:2026, IET Guidance Note 3 and the IET On-Site Guide.

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What is an acceptable R1+R2 reading?

There is no single pass or fail figure for R1+R2 — the measured value must be low enough that Zs (Ze + R1+R2) stays within the maximum for the protective device in BS 7671 Tables 41.2 to 41.4. Compare your reading against the expected R1+R2 for the cable type and length; a much higher value points to a loose or high-resistance connection.

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Key Takeaways

  • 1Continuity testing verifies that all conductors are connected end-to-end with no open circuits, and that protective conductors (CPCs) provide an unbroken path back to the main earthing terminal.
  • 2Ring final circuit testing requires two stages: an end-to-end resistance test of each conductor leg, followed by a cross-connected test to derive r1+rn (or r1+r2) at each socket outlet.
  • 3For a ring final circuit, the maximum r1+rn value at any outlet should not exceed 0.05Ω more than the value at the consumer unit end. A higher value indicates a spur rather than a ring, or an incorrect connection.
  • 4CPC continuity must be tested on every circuit. The measured r2 value (resistance of the CPC from the consumer unit to the furthest point) is used to derive Zs (total earth loop impedance) without applying live voltage.
  • 5Bonding conductor continuity testing (main and supplementary bonding) requires the bonding conductor to be temporarily disconnected from the earthed metalwork at one end to avoid the instrument current flowing through the general mass of earth.
01 · Testing Guide

What Is Continuity Testing?

Continuity testing is the verification that all conductors in an electrical installation are intact and properly connected — that current can flow unimpeded from one end of a conductor to the other with no open circuits or high-resistance joints. It is a mandatory test under BS 7671:2018+A4:2026 Chapter 64 (Reg 643.2.1) and must be carried out on all circuits during initial verification of a new installation (EIC) and during every periodic inspection (EICR).

Continuity tests cover three separate requirements:

  • Ring final circuit continuity: Verifying that socket outlet circuits wired as a ring form a complete loop with no spurious spurs or incorrectly wired connections (Regulation 643.2.1).
  • CPC continuity: Confirming that every circuit has an unbroken protective conductor connecting all exposed-conductive-parts to the main earthing terminal (Regulation 643.2.1).
  • Equipotential bonding conductor continuity: Verifying that main equipotential bonding conductors and supplementary bonding conductors are intact and properly connected (Regulation 643.2.1).

Note that Reg 643.2.1 requires live conductor (line and neutral) resistance measurement specifically for ring final circuits. For radial circuits, only the CPC continuity measurement is required under this regulation — there is no BS 7671 requirement to measure the resistance of the line and neutral conductors of a radial circuit as a separate continuity test.

Continuity tests are performed with the installation de-energised using a low-resistance ohmmeter (often a combined multifunction test instrument). The instrument injects a test current and measures the voltage drop, deriving the resistance of the conductor path.

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02 · Testing Guide

Ring Final Circuit Test 1 — End-to-End Resistance

The first stage of ring final circuit testing measures the total loop resistance of each conductor, confirming that the ring is complete and giving reference values for the cross-connected test that follows.

  1. Isolate the circuit: Switch off and isolate the circuit at the consumer unit. Prove dead at the consumer unit terminals.
  2. Disconnect the ring at the consumer unit: Disconnect both ends of the line conductor from the MCB (or fuse), both ends of the neutral from the neutral bar, and both ends of the CPC from the earth bar. You now have two separate legs of the ring — leg A and leg B.
  3. Measure end-to-end resistance of the line conductor: Join one end of leg A to one end of leg B (link the two line conductor ends together at the consumer unit). Connect the instrument between the remaining free ends of the line conductor loop. The reading is the total resistance of the line conductor around the full ring. Record this as R1 (line total).
  4. Measure end-to-end resistance of the neutral conductor: Repeat the same process with the neutral conductors. Record as Rn (neutral total).
  5. Measure end-to-end resistance of the CPC: Repeat with the CPCs. Record as R2 (CPC total).
Expected values: For a 2.5mm² line and neutral conductor (typical for a 32A ring final circuit in flat twin-and-earth cable), expect approximately 7.41Ω per km (at 20°C) for copper conductor resistance. A 30-metre ring (60m of cable length total) would give a loop resistance of approximately 0.44Ω for the line conductor. Values significantly higher than expected for the cable run length indicate a fault.
03 · Testing Guide

Ring Final Circuit Test 2 — Cross-Connected Test

The cross-connected test is the definitive ring final circuit check. It derives the r1+rn value at every socket outlet on the ring, confirming that every outlet is genuinely on the ring and not a spur, and that connections are correct throughout.

  1. Cross-connect at the consumer unit: Take one end of the line conductor (leg A) and connect it together with the opposite leg's neutral conductor (leg B neutral). Take the other line conductor end (leg B) and connect it with leg A neutral. This transposition means the instrument now sees the line of one ring leg in series with the neutral of the other.
  2. Do the same for the CPC if testing r1+r2: Cross-connect the two CPC ends together at the consumer unit (join leg A CPC end to leg B CPC end). This gives r1+r2 at each outlet when testing between line and earth.
  3. Test at each outlet: At every socket outlet on the ring, connect the instrument between line and neutral terminals. Record the resistance. This is the r1+rn value at that outlet.
  4. Test r1+r2 at each outlet: Connect the instrument between line and earth at each outlet. This gives r1+r2, which combined with Ze gives Zs.

For a correctly wired ring, the r1+rn value at every outlet should be approximately equal to one quarter of the sum of R1 and Rn (the end-to-end totals from Test 1). Outlets directly connected as spurs will show a higher reading. Outlets at opposite ends of the ring will show a reading close to R1+Rn divided by 4; outlets near the consumer unit will show a lower reading.

Figure-of-eight fault: GN3 identifies this as a specific diagnostic outcome of the three-step ring test. A figure-of-eight occurs when conductors are cross-connected at an intermediate junction — the ring appears to have end-to-end continuity in Test 1 but the conductors are actually looped back on themselves. The result is that r1+rn readings at outlets vary unexpectedly, or outlets near the cross-connection point show unusually low readings. If the end-to-end values from Test 1 appear correct but cross-connected readings are inconsistent across the ring, investigate for a figure-of-eight wiring error.
04 · Testing Guide

r1, rn, and r2 Values Explained

The lowercase notation (r1, rn, r2) refers to the resistance of the relevant conductor from the origin of the circuit to the point being tested — not the full loop resistance. These are the values recorded on the schedule of test results.

  • r1: Resistance of the line conductor from the consumer unit to the furthest point on the circuit. For a ring, derived from the cross-connected test (r1 = measured r1+rn value ÷ 2 if line and neutral have equal resistance). For a radial, measured directly.
  • rn: Resistance of the neutral conductor from the consumer unit to the furthest point. Derived from the cross-connected test. For standard flat twin-and-earth cable where line and neutral are the same size, r1 and rn are equal.
  • r2: Resistance of the CPC from the consumer unit to the furthest point. This is the most critical value. Combined with Ze, it gives Zs without applying live voltage: Zs = Ze + (r1 + r2). This calculated Zs must not exceed the maximum Zs for the protective device. GN3 (Reg 2.15) uses the notation Rz for the same value — the resistance of the CPC measured from the distribution board to each utilisation point — and records it on the Schedule of Test Results as Rz. The two notations refer to the same measurement.
Note on CPC size: In flat twin-and-earth cable, the CPC is typically smaller than the line and neutral conductors (1.0mm² CPC in 1.5mm² T&E, 1.5mm² CPC in 2.5mm² T&E). This means r2 is higher than r1 and rn, and the r1+r2 value will be higher than the r1+rn value at the same point on the ring. This is normal and expected.
05 · Testing Guide

CPC Continuity Testing

Circuit protective conductor (CPC) continuity must be verified for every circuit in the installation — not just ring final circuits. This test confirms that there is an unbroken earth path from every exposed-conductive-part back to the main earthing terminal.

  • Radial circuit method: Disconnect the CPC at the consumer unit earth bar. Use a long wander lead to connect from the disconnected CPC end at the consumer unit to the test instrument's one terminal. Connect the other terminal to the earth terminal at the furthest accessory on the circuit. The reading is r2 for that circuit.
  • Alternative method using instrument leads: Where a long wander lead is not available, the instrument can be "zeroed" with the leads joined, then the leads extended to reach the distant point. Some instruments allow lead resistance to be nulled out of the reading. Always null or compensate for lead resistance, particularly on short runs where lead resistance may be significant.
  • What constitutes a CPC?: On modern installations, the CPC is usually the bare or green-and-yellow conductor in the cable sheath. On older installations, conduit, trunking, or armour may serve as the CPC. Test the actual protective conductor, not just a parallel path that may be present.

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06 · Testing Guide

Bonding Conductor Continuity Testing

Main equipotential bonding conductors connect extraneous-conductive-parts (gas, water, and oil pipework; structural metalwork entering or passing through the building) to the main earthing terminal. Supplementary bonding connects simultaneously accessible parts in special locations (such as bathrooms). Both must be verified for continuity.

  • Disconnect at one end before testing: This is essential. If both ends of the bonding conductor remain connected, the test current flows through the general mass of earth and the general bonding network rather than through the conductor itself. The result is unreliably low and meaningless. Disconnect the bonding conductor at the metalwork clamp (not at the main earthing terminal, as this is more difficult to access safely).
  • Expected resistance values: Main equipotential bonding conductors are short and of large cross-sectional area. Under BS 7671 Reg 544.1.1 / Table 54.8, where the supply PEN conductor is 35mm² or less (the normal domestic TN-C-S case), the minimum copper main protective bonding conductor is 10mm². The resistance should be very low — typically 0.05Ω or less. Higher values indicate a poor connection at a clamp, a corroded conductor, or a join in the bonding conductor.
  • Reconnect and verify: After testing, reconnect the bonding conductor and test again with both ends connected to confirm continuity is restored. Never leave bonding conductors disconnected.
07 · Testing Guide

Test Method and Instrument Use

Continuity testing requires a low-resistance ohmmeter capable of passing a test current of at least 200mA (as specified in BS EN 61557-4). This distinguishes a proper continuity test from a simple resistance measurement — the higher current helps identify high-resistance joints that may pass at low test currents but fail under load.

  • Null the lead resistance: Before any continuity test, short the instrument leads together and record or null the lead resistance. On modern multifunction instruments this is done automatically. On analogue instruments, adjust the zero setting. Failing to null lead resistance causes every reading to be higher than the true conductor resistance by the lead resistance value.
  • Use a wander lead for distant tests: A wander lead (a long single-conductor test lead, typically 10m to 25m) allows one instrument terminal to remain at the consumer unit while the other is taken to the furthest point of the circuit. Factor the wander lead resistance into the null reading.
  • Instrument calibration: The continuity test instrument must be calibrated to a traceable standard and within its calibration period. Record the instrument make, model, serial number, and calibration expiry date on the certificate or test schedule.
08 · Testing Guide

Recording Results on the Schedule of Test Results

Continuity test results are recorded on the Schedule of Test Results, which forms part of the Electrical Installation Certificate or EICR. The following information must be recorded for each circuit:

  • r1+rn (Ω): The measured r1+rn resistance at the furthest point of the circuit, in ohms. For ring final circuits, this is the value at the furthest outlet derived from the cross-connected test.
  • r1+r2 (Ω): The measured r1+r2 resistance at the furthest point of the circuit. This is used to calculate Zs without live testing.
  • Ring final continuity: For ring final circuits, record the end-to-end values (R1, Rn, R2) from Test 1, and the r1+rn and r1+r2 values from the cross-connected test.
  • Bonding conductor continuity: Record the measured resistance of each bonding conductor tested. Note where the bonding conductor was disconnected for the test.

Continuity Testing (R1+R2): Acceptable Results (BS 7671)

How to test CPC continuity (R1+R2) and what results are acceptable. Step-by-step method, expected values and pass or fail criteria to BS 7671.

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09 · Testing Guide

For Electricians: Continuity Testing Efficiently

Continuity testing, done methodically, takes a few minutes per circuit. The steps are straightforward but must be followed in order — particularly the nulling of lead resistance and the disconnection of bonding conductors before testing.

Complete Test Schedules On Site

Use the Elec-Mate schedule of tests to enter continuity, IR, loop impedance, and RCD results on your phone as you test. The schedule auto-populates and the PDF is ready before you leave.

Derive Zs Without Live Testing

Recording accurate r1+r2 values during the continuity test means you can calculate Zs for every circuit without applying a live loop impedance test. Particularly useful where live testing is not practical or where RCDs prevent accurate live loop impedance measurement.

Frequently Asked Questions About Continuity Testing

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