From a2c3f2ab49f7b1c984692123390c61a002149179 Mon Sep 17 00:00:00 2001
From: krakenrf <78108016+krakenrf@users.noreply.github.com>
Date: Sat, 15 Oct 2022 21:39:31 +1300
Subject: Updated 08. Passive Radar (markdown)

---
 08.-Passive-Radar.md | 2 +-
 1 file changed, 1 insertion(+), 1 deletion(-)

diff --git a/08.-Passive-Radar.md b/08.-Passive-Radar.md
index f90279b..0a1d47b 100644
--- a/08.-Passive-Radar.md
+++ b/08.-Passive-Radar.md
@@ -102,7 +102,7 @@ Example cell 500, sampling rate 2.4 MHz and $N = 2^{22}$
 
 $\mathrm{Bistatic Frequency (Hz)} = f_b = 500 * \frac{2400000}{2 \times 2^{22}} = 143 \mathrm{Hz}$
 
-Then to get to speed in m/s we simply multiple the Bistatic Frequency f_b with the wavelength of the illuminator, and multiply by -1. (Positive Doppler decreases the range between you and the target so it has negative speed, it is approaching)
+Then to get to speed in $m.s^{-1}$ we simply multiple the Bistatic Frequency $f_b$ with the wavelength of the illuminator, and multiply by -1. (Positive Doppler decreases the range between you and the target so it has negative speed, it is approaching)
 
 So if we were using 560 MHz as our illuminator:
 
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