UNCLASSIFIED
TM-CAL-007
ZENER + DIVIDER MULTI-VOLTAGE REFERENCE
Temperature-Compensated Zener Diode with Precision Resistor Divider
Prepared by: Mervyn Martin, KO6NNH
Merced, California  •  26 May 2026
Amateur Radio / Electronics — Not for commercial calibration use

Table of Contents

  1. Chapter 1 — General Information
  2. Chapter 2 — Theory of Operation
  3. Chapter 3 — Materials and Construction
  4. Chapter 4 — Assembly Procedures
  5. Chapter 5 — Calibration Procedure
  6. Chapter 6 — Tuning and Adjustment
  7. Chapter 7 — Verification
  8. Appendix A — Calculations and Formulas
  9. Appendix B — Example Results

CHAPTER 1 — GENERAL INFORMATION

1-1. SCOPE

This manual covers construction of a multi-voltage reference using temperature-compensated zener diodes and precision resistor dividers. The circuit provides multiple calibrated DC reference voltages from a single stable source. Less precise than band-gap references but adequate for ±0.5% calibration work.

CHAPTER 2 — THEORY OF OPERATION

2-1. TEMPERATURE-COMPENSATED ZENER

Zener diodes exhibit a negative temperature coefficient (TC) below approximately 5.6 V and a positive TC above 5.6 V. At ~5.6 V zener voltage, TC ≈ 0. The 1N829 and LM336 are designed to operate at this compensation point.

A forward-biased diode (TC ≈ −2 mV/°C) in series with a 6.2 V zener (TC ≈ +2 mV/°C) achieves near-zero overall TC. The LM336 IC integrates this compensation internally.

Zener Reference Devices
DeviceVoltageTCAccuracyNotes
LM336-2.52.5 V<20 ppm/°C±1%Adjustable with ext R
LM385-2.52.5 V<50 ppm/°C±1%Micropower
1N8296.2 V<10 ppm/°C±0.5%Hermetic zener
1N52346.2 V<100 ppm/°C±5%General purpose

2-2. RESISTOR DIVIDER

A precision resistor divider derives lower voltages from the master reference. Use 0.1% tolerance resistors for <0.2% division error.

CHAPTER 3 — MATERIALS AND CONSTRUCTION

3-1. BILL OF MATERIALS

Components (LM336-2.5 Based)
QtyItemSpecification
1LM336Z-2.52.5 V adjustable reference
150kΩ trim potMultiturn, Bourns 3296W
210kΩ resistor0.1%, metal film, for trim network
4Precision resistor0.1% for divider outputs
2100 nF capacitorC0G, output bypass
4Banana jackColor coded per voltage
19 V batteryWith snap connector

CHAPTER 4 — ASSEMBLY PROCEDURES

  1. Connect LM336Z-2.5 with 1kΩ bias resistor from supply positive to anode (+). Connect cathode (K) to positive output terminal. Ground is common.
  2. Connect 50kΩ trimmer between ADJ pin and a midpoint in the 10kΩ divider for fine adjustment.
  3. Build precision divider: for 1.000 V from 2.500 V use R1=1.5kΩ and R2=1.0kΩ (1.000/2.500 = 0.400 ratio; choose R2/(R1+R2) = 0.400).
  4. Add 100 nF C0G capacitor at each output to suppress HF noise.
  5. Verify all connections before applying power.
  6. Apply 9 V. Measure reference output. Adjust trimmer to exactly 2.500 V using reference DMM.

CHAPTER 5 — CALIBRATION PROCEDURE

  1. Allow 15-minute warm-up.
  2. Measure master reference output. Trim to 2.500 V ±1 mV.
  3. Measure all divider outputs. Record vs. calculated values.
  4. Example: if 1.000 V nominal divider output reads 1.002 V, divider error = +0.2%, acceptable for ±0.5% calibration.
  5. If divider error exceeds ±0.5%, verify resistor values and divider wiring.

CHAPTER 6 — TUNING AND ADJUSTMENT

Use the trimmer pot to set master reference to exactly 2.500 V at room temperature. Readjust if ambient temperature changes more than 10°C.

CHAPTER 7 — VERIFICATION

  1. Verify master reference against precision voltage reference (TM-CAL-006).
  2. Verify all divider outputs match calculations within ±0.5%.
  3. Log date, temperature, and all voltages.

APPENDIX A — CALCULATIONS AND FORMULAS

Resistor divider outputVout = Vref × R2 / (R1 + R2)
Example: 1.000 V from 2.500 VR2/(R1+R2) = 0.400; e.g., R1=1.5kΩ, R2=1.0kΩ

APPENDIX B — EXAMPLE RESULTS

Zener Reference Outputs
OutputNominal (V)Measured (V)Error (mV)
Master ref2.5002.5000
Divider 11.0001.001+1
Divider 21.2501.251+1
Divider 32.0002.001+1
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