No.
Ok, now let me explain how and why. Lightning strikes originate in the clouds with a downward "stepped" leader that hops down in steps typically stated to be around 150'. That number is not a coincidence, and it directly relates to the 150' radius rolling circle (part of the UL 96A and NFPA 780 specifications) I mentioned above. We'll get back to this.
The very last "step" happens backwards. As the stepped leader approaches the ground, streamers from the ground will reach up towards it, and when they meet in the air, a conductive channel to the sky opens up, carrying thousands of amps of current in what we would think of as a lightning strike. No one can predict exactly where the stepped leader from the sky will come down, but when it does, everything within 150' of it is fair game, and that's when a lightning rod can help, by providing the best upward streamer option. In its absence, every corner of every solid object in that area is going to compete to provide the best streamer, and whatever wins (usually a gutter or antenna or chimney) takes the hit.
What about that 150'? Who made that **** up? Well, this is based on long-term observation of lightning statistics, and the actual length of both the steps in the leader and the streamer length of any given strike is directly related to the charge imbalance and final strike current flow. 91% of lightning strikes have a 150' or longer streamer (and step) length, which correlates with a 10kA or greater current flow.
Note that the streamer length marks the zone of influence of the air terminal (lightning rod). Since lightning doesn't start in clouds merely 150' from the ground, it is impossible for a lightning rod to attract lightning from the sky.
And most lightning is actually more powerful than that. A >200' step (correlates with >16kA) would catch 84% of all strikes. On the smaller end of the spectrum, a >65' radius (>3kA) covers 99% of all strikes, and >90' (>5ka) covers 97%.
So, in your example, with a strike occurring within 50' of your structure, an air terminal almost certainly would have taken that specific hit. What happens from that point depends a lot on how well your lightning protection system is engineered. Because just connecting a rod in the air with one in the ground is NOT sufficient!
But just because it could have prevented your $15k loss doesn't necessarily make a LPS worthwhile to you. The lightning frequency data shows Escondido Ca to be hit by less than one strike per square km per year. I'm in the 4 events per year zone. Most of Oklahoma's population (OP's location) seems to be in the 64 strikes per square km per year zone, with the state ranging from 24 to 96, putting it squarely in lightning country. But in both regions, a site survey can tell you if local features put your structure at greater or lesser risk.