High accuracy distance measurement by two-wavelength pulsed laser sources

Bruno Querzola

doi:10.1364/AO.18.003035

Applied Optics
Vol. 18,
Issue 17,
pp. 3035-3047
(1979)
•https://doi.org/10.1364/AO.18.003035

High accuracy distance measurement by two-wavelength pulsed laser sources

Bruno Querzola

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Bruno Querzola, "High accuracy distance measurement by two-wavelength pulsed laser sources," Appl. Opt. 18, 3035-3047 (1979)

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Abstract

The two-wavelength method, proposed by P. L. Bender and J. C. Owens, makes it possible to achieve fractional accuracies of better than 10⁻⁶ (1 ppm) in ranging. The technique has only been applied to continuous laser sources. This paper attempts to ascertain whether high power pulsed lasers can be successfully used with this method and to check the system feasibility from an experimental viewpoint. Instead of phase comparison techniques (typical of cw systems), the pulse sources involve direct transit time measurements. The consequent average of N measurements can reduce the error on the distance mean value by an N^−1/2 factor. The main cause of error concerns threshold crossing in pulse discrimination, especially in the presence of amplitude fluctuations. Causes of error affecting such measurements are analyzed. Results are reported of measurements at distances of 5 km and 13 km by pulsed ruby laser PTM emission (λ = 6943 Å) and its second harmonic (λ = 3472 Å) using a timer with 20-psec accuracy. Such measurements show that two-wavelength pulsed laser telemeters can reach 1-ppm accuracies for distances exceeding a few kilometers: over large distances (greater than 50 km, under favorable visibility conditions), such high power pulsed telemeters appear to be the only ones to achieve this accuracy.

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T(kelvin)	n (%)	f (Torr)	17 f/T	$0.186 σ_{r}^{2} f / T$	0.186σ_uf/T	A_rf/T	B f/T	D
273	50	2.3	0.14	0.0028	0.0112	0.14	0.071	0.21
	100	4.6	0.27	0.0061	0.0244	0.26	0.15	0.41
283	50	4.6	0.27	0.0062	0.0248	0.26	0.16	0.42
	100	9.2	0.55	0.012	0.048	0.54	0.31	0.85
293	50	8.7	0.50	0.012	0.048	0.49	0.30	0.79
	100	17.5	1.02	0.024	0.096	0.98	0.60	1.6
303	50	16.0	0.90	0.023	0.092	0.88	0.53	1.47
	100	32.0	1.80	0.047	0.174	1.75	1.18	2.93

T (kelvin)	273	283	293	303
$\frac{Δ L}{L} (D) ~ Δ D (ppm)$	0.06	0.10	0.19	0.35

λ (Å)	Color	(n_SG − 1) × 10⁻⁶	Δn_SG ×10⁶	$\frac{Δ n_{S G}}{Δ λ} \times 10^{8} (A)$
10600	Infrared	276.751	—	—
8600	Infrared	278.944	2.20	0.11
7600	Near infrared	280.767	1.823	0.18
6910	Red	282.532	1.765	0.256
6328	Red	284.515	1.983	0.341
5792	Yellow	286.970	2.455	0.458
5462	Green	288.859	1.879	0.569
4801	Blue	293.949	5.10	0.771
4359	Blue	298.848	4.90	1.111
4048	Violet	303.480	4.63	1.489
3656	UV	311.315	7.835	1.999
3133	UV	327.951	16.616	3.177
2577	UV	362.768	34.837	6.155

	$\frac{Δ n_{S G 2}}{Δ λ} (Å)$	$\frac{Δ n_{S G 1}}{Δ λ} (Å)$	$\frac{Δ α}{Δ λ} (Å)$	$\frac{1}{Δ λ} \frac{Δ L}{L} (\frac{ppm}{Å})$
Pulsed 2-λ system	2 × 10⁻⁸	2.5 × 10⁻⁹	6 × 10⁻⁵	0.15
(λ₁ = 6943 Å; λ₂ = 3472 Å)
Georan3	7 × 10⁻⁹	7 × 10⁻⁹	3 × 10⁻⁵	0.45
(λ₁ = 5145 Å; λ₂ = 4580 Å)
Telemeter from Ref. 2	3.4 × 10⁻⁹	11 × 10⁻⁹	4 × 10⁻⁵	0.25
(λ₁ = 6328 Å; λ₂ = 4416 Å)

T(kelvin)	n (%)	f (Torr)	17 f/T	$0.186 σ_{r}^{2} f / T$	0.186σ_uf/T	A_rf/T	B f/T	D
273	50	2.3	0.14	0.0028	0.0112	0.14	0.071	0.21
	100	4.6	0.27	0.0061	0.0244	0.26	0.15	0.41
283	50	4.6	0.27	0.0062	0.0248	0.26	0.16	0.42
	100	9.2	0.55	0.012	0.048	0.54	0.31	0.85
293	50	8.7	0.50	0.012	0.048	0.49	0.30	0.79
	100	17.5	1.02	0.024	0.096	0.98	0.60	1.6
303	50	16.0	0.90	0.023	0.092	0.88	0.53	1.47
	100	32.0	1.80	0.047	0.174	1.75	1.18	2.93

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Applied Optics